JP2005198767A - Method and apparatus of processing unused agricultural chemical - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a method and an apparatus of processing an unused agricultural chemical with which so-called unused agricultural chemical, particularly a solid-state agricultural chemical which is buried in the ground or stored and left in a farm house or the like after it is banned is processed without generating a lot of secondary contaminant so that a working environment can be kept safe, and organic halogen in the solid-state unused agricultural chemical such as an organic chlorine compound or the like can be appropriately decomposed and processed. <P>SOLUTION: The method of processing the unused agricultural chemical is characterized in that a solvent is added to the solid-state unused agricultural chemical including a halogen compound to extract an organic halogen compound into the solvent to separate from a solid body, and in that the organic halogen compound extracted in the solvent is decomposed by an alkali metal for dehalogenation. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

  The present invention relates to a method and apparatus for treating residual agricultural chemicals used, and more specifically, a so-called residual agricultural chemical used that is buried in the soil after being prohibited from use or left stored in a farmhouse. In particular, the present invention relates to a solid pesticide treatment method and apparatus.

  Conventionally, pesticides containing organic halogens such as organic chlorine compounds such as DDT, hexachlorocyclohexane (BHC), and hexachlorobenzene (HCB) have been widely used because of their excellent pest control effects. Residual or bioconcentration causes these drugs to behave in a manner similar to the original biohormones, demonstrating a significant impact on the ecosystem, such as loss of normal reproductive function (environmental hormones, endocrine disruptors, etc.) Currently, its use is prohibited. Since the use of these pesticides has been banned, the remaining ones are buried in the soil, left as they are stored by farmers, or collected and stored by pesticide manufacturers. These pesticides are also called residual agricultural chemicals.

  Among these residual agricultural chemicals, those that are stored at farms or collected by manufacturers, but those that are buried in the soil and left for many years may cause environmental damage depending on the storage conditions, The impact on the ecosystem cannot be ignored.

Therefore, in recent years, the remaining agricultural chemicals buried in the soil and left for many years are dug up and treated. These organohalogen pesticides are included in persistent organic pollutants and are required to be treated systematically in the future under the Stockholm Convention adopted in May 2001. In the case of treating such residual agricultural chemicals, a method of incineration has been conventionally employed as shown in Patent Document 1 and Patent Document 2 below.
JP2003-284920A JP 2001-70470 A

  However, incineration of agricultural chemicals containing halogen compounds such as chlorine has the problems that the furnace life is shortened by halogens such as chlorine, and that secondary contaminants such as dioxins may be generated. there were. In addition, when treating agricultural chemicals stored at farms or agricultural chemicals collected by manufacturers, there is a problem of generation of dioxins due to inevitable use of incineration means.

  The present invention has been made to solve all of the above-mentioned problems, and it is possible to maintain a safe working environment with less generation of secondary contaminants. It is an object of the present invention to provide a method and apparatus for treating residual agricultural chemicals that can suitably decompose organic halogens such as chlorine compounds.

  The present invention has been made to solve such problems, and the invention according to claim 1 is an invention of a method for treating residual agricultural chemicals used, and is a solvent for solid residual agricultural chemicals containing halogen compounds. And the organic halogen compound in the agricultural chemical is extracted from the solid and separated from the solid, and the organic halogen compound extracted in the solvent is decomposed with an alkali metal and dehalogenated.

  The invention according to claim 2 is that in the method for treating residual agricultural chemicals according to claim 1, the solvent for extracting the organic halogen compound in the agricultural chemical is an aliphatic hydrocarbon, kerosene, or a kerosene-derived solvent. Features. Furthermore, the invention according to claim 3 is characterized in that, in the method for treating residual agricultural chemicals according to claim 1 or 2, the solid residual agricultural chemicals are dried before the solvent is added.

  Furthermore, the invention described in claim 4 is an apparatus for treating residual agricultural chemicals, wherein a solvent is added to a solid residual residual agricultural chemical containing a halogen compound to extract an organic halogen compound in the agricultural chemical into the solvent. And a means for dehalogenating the organohalogen compound in the pesticide extracted in the solvent with an alkali metal.

  Furthermore, the invention described in claim 5 is characterized in that in the used residual agricultural chemical treatment apparatus according to claim 4, a means for drying the solid residual residual agricultural chemical is added before the solvent is added.

  As described above, in the present invention, a solvent is added to a solid residual agricultural chemical containing a halogen compound, an organic halogen compound in the agricultural chemical is extracted into the solvent, separated from the solid content, and the organic halogen extracted in the solvent is extracted. Since the compound is decomposed by alkali metal and dehalogenated, there is little generation of secondary contaminants, the work environment can be kept safe, and organic halogens such as organic chlorine compounds in solid residual agricultural chemicals can be removed. There exists an effect that it can be made to decompose suitably.

  In particular, when an aliphatic hydrocarbon, kerosene, or a kerosene-derived solvent is used as a solvent, these solvents do not react with alkali metals, and wasteful consumption of alkali metals can be more reliably prevented. effective.

  Furthermore, when the solid residual agricultural chemicals are dried before the solvent is added, the solid agricultural chemicals are suitably dispersed in the solvent, and it is easier to separate the agricultural chemicals from the solids accordingly. There are advantages.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. First, a processing apparatus for residual agricultural chemicals as one embodiment will be described.

  As shown in FIG. 1, the processing apparatus for residual agricultural chemicals of the present embodiment causes a drying apparatus 1 for drying solid residual agricultural chemicals, and solvent extraction of the solid agricultural chemical dried by the drying apparatus 1. And a dechlorination device 3 for dechlorinating the pesticide extracted in the solvent.

  The drying apparatus 1 heats and dries the solid used residual agricultural chemical, and moisture is evaporated by drying to be removed from the solid agricultural chemical.

  The solvent extraction device 2 is for adding a solvent to extract an organochlorine compound in an agricultural chemical into the solvent, and the solid content is separated by such extraction.

  The dechlorination apparatus 3 is for decomposing an organic chlorine compound by adding a sodium dispersion in which metallic sodium is dispersed in an insulating oil. The dechlorination apparatus 3 has a structure in which a stirring blade 5 is provided in a tank body 4 as shown in FIG. As shown in the figure, the stirring blade 5 has a configuration in which paddle blades 8a, 8b are vertically attached to two upper and lower stages of a rotating shaft 7 driven by a motor 6, and the upper and lower paddle blades 8a , 8b are not clearly shown, but are arranged at a 45 degree crossing angle. The dechlorination apparatus 3 is purged with nitrogen gas to form a nitrogen atmosphere.

  Furthermore, a hydration tank 9, a neutralization tank 10, and an oil / water separator 11 are provided on the rear side of the dechlorination apparatus 3. The hydration tank 9 is for hydrating the sodium dispersant that has not been consumed in the dechlorination apparatus 3, and water is added to the hydration tank 9.

  Further, the neutralization tank 10 is for neutralizing the alkali generated by the hydration reaction in the hydration tank 9, and carbon dioxide gas is added to the neutralization tank 10. Furthermore, the oil / water separator 11 is for oil-water separation of the treated water after hydration and neutralization. An activated carbon treatment device 12 for purifying the treated water after the oil / water separation is provided on the rear side of the oil / water separator 11.

  Further, a condensing device 13 for condensing water evaporated by heating and drying in the drying device 1, a drying device 14 for drying solids separated by the solvent extraction device 2, and exhaust gas generated from the dechlorination device 3 Activated carbon treatment devices 15 for adsorbing the agricultural chemical components therein are provided.

  Next, an embodiment of a method for treating residual agricultural chemicals using the above-described residual agricultural chemical treatment apparatus will be described.

  First, solid residual agricultural chemicals are supplied to the drying apparatus 1. This solid residual agricultural chemical is a solid agricultural chemical buried in the soil, a solid agricultural chemical that has been stored in a farmhouse, or a solid agricultural chemical recovered by the manufacturer. However, both remain and require processing.

  In this case, the agrochemicals stored and left by the farmers and the pesticides collected by the manufacturer are supplied to the drying device 1 as they are, but the residual agricultural chemicals in the soil are packaged in plastic bags etc. Since the container is buried and filled in the hollow part of a concrete pipe that has been buried in the ground in advance, the residual agricultural chemicals in such a state are dug out of the soil, vinyl After separating from bags, containers, concrete scraps, soil, etc., solid agricultural chemicals are supplied to the drying device 1 as described above.

  The solid residual agricultural chemicals supplied to the drying device 1 are heated and dried by the drying device 1. The solid agrochemical after drying is supplied to the solvent extraction device 2, and the water vapor evaporated by drying is supplied to the condensing device 13.

  The solid agricultural chemical from which moisture has been removed by drying is supplied to the solvent extraction device 2, and the solvent extraction device 2 is supplied with a solvent, and the solvent extracts chlorine compounds in the agricultural chemical from the solid agricultural chemical. Will be. In this case, aliphatic hydrocarbons such as normal paraffin and isoparaffin are used as the solvent in this embodiment.

  The solvent separated from the solid content and extracted with the organic chlorine compound is supplied to the dechlorination apparatus 3. Then, in the dechlorination apparatus 3, the organic chlorine compound is decomposed by the metallic sodium in the metallic sodium dispersion. That is, a sodium dispersion in which metallic sodium is dispersed in an insulating oil is added to the dechlorination apparatus 3, and the metallic sodium in the sodium dispersion reacts with the agricultural chemical in the extraction solvent, and the organochlorine compound is dechlorinated. It will be broken down and decomposed. At this time, isopropyl alcohol as a reaction accelerator is added.

  Then, excess metallic sodium that has not been consumed in the dechlorination apparatus 3 is supplied to the next hydration tank 9. Water is supplied to the hydration tank 9 and the unconsumed metallic sodium is hydrated. In this hydration tank 9, alkali is generated by the hydration reaction of metallic sodium, so the treated water after hydration is supplied to the neutralization tank 10 and neutralized. That is, carbon dioxide gas is supplied to the neutralization tank 10, and the carbon dioxide gas reacts with the alkali to be neutralized.

  The treated water neutralized in the neutralization tank 10 is supplied to the oil / water separator 11 and separated into oil / water. The oil after the oil-water separation is recovered as treated oil, and the water is supplied as treated water to the activated carbon treatment device 12 and treated with the activated carbon treatment device 12 even if a small amount of organochlorine compound is contained in the treated water. The organic chlorine compound in the water is adsorbed by the activated carbon, and only the treated water containing no organic chlorine compound is discharged out of the system as waste water. The recovered treated oil can be reused as a solvent.

  On the other hand, the water vapor evaporated by the drying device 1 and supplied to the condensing device 13 is condensed by the condensing device 13 and supplied to the activated carbon treatment device 12 as condensed water. Organochlorine compounds in agricultural chemicals are held in the solid content dried by the drying device 1 and supplied to the solvent extraction device 2 and should not exist in the condensed water originally, but a small amount of organic in the condensed water. Even if the chlorine compound is contained, the organochlorine compound is adsorbed on the activated carbon of the activated carbon treatment device 12, and only treated water containing no organochlorine compound is discharged out of the system.

  Further, the solid content removed by solvent extraction of the organic chlorine compound in the agricultural chemical by the solvent extraction device 2 is supplied to the drying device 14 and dried by heating, and the solvent is evaporated together with the solvent from which the agricultural chemical is extracted. Supplied to the dechlorination apparatus 3. Further, the solid material dried by the drying device 14 is recovered as a processing residue.

  Further, the exhaust gas from the dechlorination apparatus 3 is supplied to the activated carbon treatment apparatus 15. And even if a trace amount of organic chlorine compound is contained in the exhaust gas from which the organic chlorine compound is decomposed and removed by the dechlorination apparatus 3, the organic chlorine compound is adsorbed on the activated carbon of the activated carbon treatment apparatus 15 and becomes organic. Only the exhaust gas containing no chlorine compound is discharged outside the system.

  As described above, in this embodiment, the solid used residual agricultural chemical is supplied to the drying device 1 and dried, and then supplied to the solvent extraction device 2 to add the solvent. Is extracted to the solvent side, and only the pesticide extracted by the solvent is supplied to the dechlorination apparatus 3 in a state of being separated from the solid content and extracted to the solvent side.

  Further, since the solid agricultural chemical is dried by the drying apparatus 1 and the moisture is removed and then supplied to the solvent extraction apparatus 2, the solid agricultural chemical is suitably dispersed in the solvent. It becomes easy to separate the organic chlorine compound from the water. Moreover, it is preferable to grind the agricultural chemical dried with the drying apparatus with a stirring mill etc. in order to make solvent extraction easy.

  In the above embodiment, aliphatic hydrocarbons such as normal paraffin and isoparaffin are used as the solvent. However, the type of the solvent is not limited to this, and kerosene, kerosene-derived solvent, etc. can also be used. It is.

  In the sense of extracting an organic chlorine compound, alcohol solvents such as isopropyl alcohol, ethanol, and methanol, ketone solvents such as acetone, ether solvents such as ethyl ether, and the like can be used. In addition, aromatic hydrocarbons such as toluene, xylene and alkylbenzene, and alicyclic hydrocarbons such as cyclohexane can also be used.

  However, since the alcohol solvent, ketone solvent, and ether solvent react with the alkali metal, the alkali metal is inadvertent when supplied to the dechlorination apparatus 3 even if the organic chlorine compound can be extracted. There is a problem of being consumed. Aromatic hydrocarbons and alicyclic hydrocarbons are not preferred because when the surplus alkali metal is hydrated in the hydration tank 9, the solvent is eluted into the water tank and drainage treatment is required.

  Therefore, in consideration of these points, it is desirable to use the aliphatic hydrocarbons, kerosene, kerosene-derived solvents and the like as described above. In this case, it is preferable to use a boiling point in the range of 100 to 300 ° C. Incidentally, the boiling point of normal paraffin is about 171 to 227 ° C, and the boiling point of kerosene is about 150 to 270 ° C.

  Furthermore, the temperature at which the organochlorine compound separated from the agricultural chemical in the dechlorination apparatus 3 is reacted with the sodium dispersion is not particularly limited, but is preferably about 30 to 100 ° C.

  The ratio of the alkali metal to chlorine is preferably about 1 to 10 mol when the contaminated oil obtained by extracting the organic chlorine compound with a solvent is high, and preferably about 10 to 1000 mol when the concentration is low.

  Furthermore, although the metallic sodium used as what makes the decomposition | disassembly reaction of an agricultural chemical in the dechlorination apparatus 3 of the said embodiment has an advantage which is cheap and generally easily available, it is not restricted to this, Metal potassium, Metal strontium, It is also possible to use metallic lithium or an alloy thereof. That is, a dispersion in which an alkali metal is dispersed in a dispersion medium such as oil may be used.

  Furthermore, the type of agricultural chemicals used in the present invention is not limited, such as DDT or BHC. In addition, the properties of the agrochemicals are, for example, those obtained by attaching agrochemicals to a bulking agent such as bentonite and clay to form granules, powders, etc. Any property is not required. In short, it may be solid.

Furthermore, although the said embodiment demonstrated the case where the agrochemical containing an organic chlorine compound was processed, it is also possible to apply this invention to the treatment of the agrochemical containing organic halogen compounds other than chlorine.
In the present invention, “agrochemicals containing an organic halogen compound” means, for example, when an agrochemical is granular, it contains a bulking agent in addition to the original medicinal ingredients such as DDT and BHC, or the agrochemical is a powder. In some cases, about 90% of inorganic assistants are contained to facilitate dissolution and dispersion at the time of spraying, and the whole including these inorganic assistants and extenders are agricultural chemicals. Only means an organic halogen compound.

  The used residual agricultural chemical treatment method and apparatus of the present invention are agricultural chemicals that remain in the soil or are stored as they are, and can be applied to solid agricultural chemicals.

The schematic block diagram of the processing apparatus of the residual pesticide used as one Embodiment. FIG. The schematic front view of the dechlorination apparatus in a processing apparatus.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 ... Drying apparatus 2 ... Solvent extraction apparatus 3 ... Dechlorination apparatus

Claims (5)

  It is characterized by adding a solvent to the solid residual agricultural chemicals containing halogen compounds, extracting the agricultural chemicals in the solvent and separating them from the solids, decomposing the extracted agricultural chemicals in the solvent with an alkali metal and dehalogenating them. A method for treating residual agricultural chemicals.   The method for treating residual agricultural chemicals according to claim 1, wherein the solvent for extracting the agricultural chemical is an aliphatic hydrocarbon, kerosene, or a kerosene-derived solvent.   The method of treating residual agricultural chemicals according to claim 1 or 2, wherein the solid residual agricultural chemicals are dried before adding the solvent.   A means for adding a solvent to a solid residual pesticide containing a halogen compound, extracting the pesticide in the solvent and separating it from the solid content, and a means for dehalogenating the pesticide extracted in the solvent with an alkali metal And a residual pesticide treatment apparatus.   The processing apparatus for used residual agricultural chemicals according to claim 4, comprising means for drying the solid residual agricultural chemicals before adding the solvent.