JP2002233859A - Method for decontaminating contaminated soil containing oleaginous harmful substance or the like and facility and system therefor - Google Patents

Abstract

PROBLEM TO BE SOLVED: To complete treatment in a process up to dehydration filtration in a weight reduction disposal method, to reduce the risks involved in decontamination treatment and to lower the cost of disposal in relation to the decontamination of contaminated soil containing oleaginous and persistent harmful substances such as dioxins. SOLUTION: A permeable housing tool housing an adsorbent which selectively adsorbs oleaginous harmful substances is put in slurried contaminated soil containing oleaginous harmful substances, the soil is agitated to adsorb the harmful substances on the adsorbent and then the housing tool is separated from the soil. By this method, the oleaginous contaminants are efficiently treated, and since the contamination degree of the remaining contaminated soil is sufficiently low, the sealing treatment of the soil is easily and safely carried out even when the volume is huge.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

The present invention relates to contaminated sediment or contaminated soil containing dioxins or so-called oleaginous and hardly decomposable harmful substances such as PCB (hereinafter referred to as condensed when it is not necessary to distinguish them). The present invention also relates to a method for purifying hazardous waste, a purification facility and a purification system therefor.

[0002]

2. Description of the Related Art Dioxins and PCBs are known as oleaginous (fat-soluble) and hardly decomposable harmful substances. Even if they are extremely small, if they flow into the environment, they are taken into the human body through the polluted environment. However, it has a bad effect on human health, and measures for its purification or containment are urgent issues. Conventionally, as a purification measure, a method of purifying this hardly decomposable harmful substance by physical thermal decomposition or chemical decomposition (BCD method, geomelt method) for a long time, heat separation in an enclosed space, Thereafter, a method of purifying by a thermal desorption method of coagulating and recovering by cooling is adopted.
However, these purification methods have high processing costs, and thus have been difficult to apply economically when the amount to be purified is large. In the latter case, the treatment of contaminants after separation remains as an issue. Furthermore, these methods require some heating step, and there is a risk of cross-contamination if improper treatment is performed in this heating step.

On the other hand, dioxins and PCB harmful substances contained in soil / water bottom mud or harmful waste (hereinafter referred to as “contaminated soil etc.”) have relatively low concentrations of harmful substances. In this case, a method of solidifying contaminated soil and hazardous waste with a solidifying material such as cement and then sealing it in a space blocked or blocked by a water-blocking sheet or a water-blocking ground wall (solidification method) It is generally adopted because the processing cost is relatively low. However, in this method, the amount of contaminated soil increases due to the addition of the solidifying material and the like, and since there is low-concentration toxicity, detoxification of the contaminated soil cannot be achieved even by the effect of adding and diluting the solidifying material. In addition, since it is hard to decompose, it is necessary to manage a large amount of pollutants without being permanently decomposed and purified, which is not practical. Therefore, a method of reducing the amount of decontaminated soil by dehydration and weight reduction instead of solidification treatment is being studied. However, under the current situation, the contamination concentration increases due to the reduction in dehydration, and a large amount of harmful substances contained in the drainage water after dehydration is generated. Therefore, the purification treatment risk is still high, which is a bottleneck for practical use. In order to overcome this problem, it is necessary to solve problems such as upgrading the disposal device of dewatered filtered water and reducing disposal costs.

[0004]

DISCLOSURE OF THE INVENTION The present invention has been made in view of the above circumstances, and a method for purifying contaminated soil or the like containing oily and harmful substances by dehydration reduction (reduction disposal method). It is an object of the present invention to provide a purification method capable of reducing the risk of a purification treatment and improving the disposal cost by improving the treatment in the treatment process leading to filtration. It is another object of the present invention to provide a purification facility, a purification system, and a device for performing the method. For this reason, the present invention provides that a specific adsorbent, particularly a copper phthalocyanine-based polycyclic aromatic adsorbent, effectively adsorbs harmful oily substances, and a fiber / cloth to which the adsorbent is attached is attached to a specific device. The present invention has been made based on the finding that by performing a predetermined operation by incorporating the above into a contaminated soil, it is possible to effectively and efficiently treat contaminated soil and the like.

[0005] The harmful oily substances targeted in the present invention specifically refer to dioxins and PCBs.
Regarding dioxins, polychlorinated dibenzo-para-dioxins (PCDDs, 2.3.7.8-TCD)
D is included in this), polychlorinated dibenzofuran (P
CDFs) as representative examples, including those showing properties equivalent to these. For PCBs, coplanar PCBs are mentioned. These have in common that they consist of two benzene rings (two rings), are hardly decomposable, are fat-soluble organic substances, and have strong toxicity. It should be noted in the present invention that these dioxins and PCBs are composed of two benzene rings, that is, two rings, and the present inventors show that the above-mentioned copper phthalocyanine also exhibits an effective adsorption effect on these. That's what I found. The oleaginous harmful substances in the present invention further include so-called persistent organic pollutants (POPs), which are also two-ring substances, and are not limited to two-ring substances, but show the same properties. As such,
Chlordane, DDT, aldrin, dieldrin, endrin, heptaclone (two or more rings), toxaphene, H
CB, Mailex, Endosulfan, PCP, HC
H and the like.

[0006]

The method for purifying contaminated soil containing oily and harmful substances, the purification equipment and the purification system according to the present invention specifically employ the following technical means (configuration). The first invention relates to a method for purifying contaminated soil and the like containing harmful substances, and as described in claim 1, slurries contaminated soil and the like containing oleaginous harmful substances, A permeable container containing an adsorbent for selectively adsorbing a substance is mixed and stirred into the slurried contaminated soil, and the harmful substances contained in the contaminated soil are adsorbed on the adsorbent. Thereafter, the storage device is separated from the soil to be purified. Here, the “contaminated soil and the like” includes soil at the surface containing oleaginous (also referred to as fat-soluble) harmful substances, sediment at the water bottom (contaminated sediment), or harmful waste equivalent thereto. In the above configuration, after collecting contaminated soil and the like containing oleaginous harmful substances, slurrying the contaminated soil, and prior to treatment with the adsorbent, harmful microbubbles to the slurried contaminated target soil. Inserting and adding a treatment for primary removal of the substance, the adsorbent is selected from fibers attached with an adsorbent that selectively adsorbs oleaginous harmful substances, or granular activated carbon, Means that the adsorbent applied to the adsorbent is a copper phthalocyanine-based polycyclic aromatic adsorbent, and the adsorbent that has adsorbed harmful substances is separated from the soil to be purified and then treated while adsorbing the harmful substances. Or
It is a technical matter appropriately selected that the harmful substance is separated from the soil to be purified and used again after washing the harmful substance, and that the contaminated soil is sediment on the bottom of the water. (Action) The adsorbent selectively adsorbs harmful substances, and the harmful substances are reliably removed from the soil to be contaminated. The processing load of this adsorber is small, exhibits a large removal rate, and the adsorption capacity is maintained for a long time. In addition, the adsorbent is not directly disposed of by heat treatment or the like, but can be reused after cleaning contaminants, thereby improving efficiency. When a step of introducing fine bubbles to remove harmful substances in contaminated soil is added, the purification rate of harmful substances in muddy water is further increased.

The second invention relates to a method for purifying contaminated soil and the like containing other harmful substances. As described in claim 2, the contaminated soil and the like containing oleaginous harmful substances are slurried. A permeable container containing an adsorbent for selectively adsorbing oleaginous harmful substances is mixed and stirred into the slurried contaminated soil to remove the harmful substances contained in the contaminated soil. After that, the storage device is separated from the soil to be purified, and the remaining soil to be purified is dehydrated with a filter cloth containing an adsorbent having an action equivalent to that of the adsorbent. And In the above configuration, after collecting contaminated soil and the like containing oleaginous harmful substances, slurrying the contaminated soil, and prior to treatment with the adsorbent, harmful microbubbles to the slurried contaminated target soil. Inserting and adding a treatment for primary removal of the substance, the adsorbent is selected from fibers attached with an adsorbent that selectively adsorbs oleaginous harmful substances, or granular activated carbon, Means that the adsorbent applied to the adsorbent is a copper phthalocyanine-based polycyclic aromatic adsorbent, and the adsorbent that has adsorbed harmful substances is separated from the soil to be purified and then treated while adsorbing the harmful substances. Or
A technique that is appropriately selected to be used after washing the harmful substances after being separated from the soil to be purified, and that the contaminated soil be sediment at the bottom of the water, and that the filter cloth be dehydrated at high pressure. Matters. (Function) Since the filter cloth uses an adsorbent that selectively adsorbs harmful substances, it reliably captures contaminants in contaminated soil sent under high pressure, so that contaminated soil is effectively purified. You. When a step of introducing fine bubbles to remove harmful substances in contaminated soil is added, the purification rate of harmful substances in muddy water is further increased.

[0008] The third invention relates to a facility for purifying contaminated soil and the like containing harmful substances. As set forth in claim 8, a method for purifying contaminated soil and the like containing oily harmful substances and slurrying the same is provided. A permeable container containing an adsorbent for selectively adsorbing oleaginous harmful substances is mixed and stirred into the slurried contaminated soil, and the harmful substances contained in the contaminated soil are adsorbed to the adsorbent. It is characterized by having at least a function of adsorbing and separating the storage device from the contamination purification target. This purification facility is effective for sandy soil and bottom mud (silty soil). The fourth invention relates to a facility for purifying contaminated soil and the like containing other harmful substances. As described in claim 9, oil-and-fat harmful substances and slurry of contaminated soil and the like are removed from oil and fat. A filter cloth provided with an adsorbent for selectively adsorbing harmful substances having a property of causing the harmful substances contained in the contaminated soil to be adsorbed by the adsorbent and dehydrating at a high pressure. . The present purification equipment is effective for bottom mud (silty soil), but is also applicable to sandy soil.
In each of the above structures, the adsorbent contains a harmful substance characterized in that either an adsorbent for selectively adsorbing oleaginous harmful substances is attached to the fiber or granular activated carbon is selected. Is a technical matter that is appropriately adopted.

A fifth aspect of the present invention relates to a system for purifying contaminated soil or the like containing harmful substances, which is characterized by comprising the following element system. (1) A system for excavating and dredging contaminated soil containing oily and toxic substances. (2) A system in which the excavated and dredged soil is slurried by water mixing. (3) A system that removes obstacles and coarse particles contained in the slurried contaminated soil. (4) A system for primary removal of harmful substances using microbubbles from polluted soil in slurry. (5) To the residual contaminated soil in the primary removal, the harmful substance contained in the contaminated soil is adsorbed to the adsorbent by an adsorbent for selectively adsorbing oleaginous harmful substances, and the secondary removal of harmful substances is performed. (6) A system that concentrates contaminated soil remaining after secondary removal. (7) Concentrated secondary contaminated residual soil, contained in the contaminated soil by a filter cloth equipped with an adsorbent impregnated with fibers, an adsorbent that selectively adsorbs oily harmful substances A system in which the harmful substances are adsorbed on the adsorbent and dehydrated at high pressure. (8) A system to confirm the harmlessness of the drainage of the previous (7) system. (9) Dewatering and weight reduction treatment of the previous (7) system. In the above configuration, the adsorbent may be selected from one in which an adsorbent for selectively adsorbing oleaginous harmful substances is attached to the fiber, or granular activated carbon, and furthermore, the adsorbent applied to the adsorber may be used. The fact that the agent is a copper phthalocyanine-based polycyclic aromatic adsorbent is a technical matter appropriately adopted.

A sixth aspect of the present invention relates to another purification system for contaminated soil or the like containing harmful substances, characterized by comprising at least the following element systems. (1) A system for excavating and dredging contaminated soil and contaminated sediment containing oily and toxic substances. (2) A system in which the excavated and dredged soil is slurried by water mixing. (3) To the slurry of the soil to be contaminated, the harmful substances contained in the contaminated soil are adsorbed to the adsorbent by an adsorbent that selectively adsorbs oleaginous harmful substances to remove the harmful substances. Eggplant system. This purification system is effective for sandy soil and bottom mud (silty soil). A seventh aspect of the present invention relates to a further purification system for contaminated soil or the like containing harmful substances, which is characterized by comprising at least the following element systems. (1) A system for excavating and dredging contaminated soil and contaminated sediment containing oily and toxic substances. (2) A system in which the excavated and dredged soil is slurried by water mixing. (3) The filter cloth equipped with an adsorbent for selectively adsorbing oleaginous harmful substances to the slurried contaminated target soil,
A system in which harmful substances contained in the contaminated soil are adsorbed on the adsorbent and dehydrated at high pressure. This purification system
It is effective for bottom mud (silty soil), but is also applicable to sandy soil. An eighth aspect of the present invention relates to a further purification system for contaminated soil or the like containing harmful substances, as described in claim 14, characterized by comprising at least the following element systems. (1) A system for excavating and dredging contaminated soil and contaminated sediment containing oily and toxic substances. (2) A system in which the excavated and dredged soil is slurried by water mixing. (3) To the slurry of the soil to be contaminated, the harmful substances contained in the contaminated soil are adsorbed to the adsorbent by an adsorbent that selectively adsorbs oleaginous harmful substances to remove the harmful substances. (4) A filter cloth provided with an adsorbent for selectively adsorbing oleaginous harmful substances with respect to the remaining contaminated soil of the system of (3), whereby harmful substances contained in the contaminated soil are removed. A system for adsorbing the adsorbent and dehydrating at high pressure. In the sixth to eighth aspects of the present invention, a system is provided between the systems (2) and (3) for primary removal of harmful substances by microbubbles from the slurried contaminated soil. It is a technical matter that is appropriately adopted that the adsorbent is made of a fiber in which an adsorbent for selectively adsorbing oleaginous harmful substances is adsorbed to fibers or a granular activated carbon is selected. .

A ninth invention relates to an apparatus (member) used for purifying contaminated soil and the like containing harmful substances, and as described in claim 17, is mixed and stirred into slurry contaminated soil. The present invention also relates to a permeable container containing an adsorbent for selectively adsorbing oleaginous toxic substances contained in the contaminated soil. In the above configuration, the adsorbent may be selected from one in which an adsorbent for selectively adsorbing oleaginous harmful substances is attached to the fiber, or granular activated carbon, and furthermore, the adsorbent applied to the adsorber may be used. The fact that the agent is a copper phthalocyanine-based polycyclic aromatic adsorbent is a technical matter appropriately adopted.

[0012]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS An embodiment of a method for purifying contaminated soil or the like containing oleaginous harmful substances, its purification equipment and a purification system according to the present invention will be described with reference to the drawings. (First Embodiment) FIGS. 1 to 6 show an embodiment of a purification system for carrying out a method for purifying weight loss of contaminated soil or the like containing oily and harmful substances according to the present invention and purification equipment in the purification system (first embodiment). Embodiment) is shown. That is, FIGS. 1 to 3 show the overall configuration of the present purification system, and FIGS. 4 to 6 show the detailed structure of each part thereof.

The present embodiment is particularly directed to polluted sediment (including sludge) on the water bottom. This is mainly composed of fine soil particles of clay and silt, and has a high moisture content. As described above, the consolidation treatment of contaminated bottom mud by adding a consolidation agent merely increases the volume, and there is no effective solution.

1 to 3 show the overall configuration of the purification system of the present invention. This system is composed of the following element systems. First system: A system for excavating and dredging contaminated soil and contaminated sediment containing harmful substances (I in the figure, hereinafter referred to as a "mining system"). Second system: Water is added to the excavated and dredged contaminated soil to be purified to obtain the necessary fluidity for adsorption of harmful substances to be treated and prior removal of organic substances including harmful substances, and kneading and slurrying. System (II in the figure, hereafter referred to as “water-mixing system”). Third system: A system that removes obstacles and coarse particles that hinder the separation of harmful substances from contaminated slurried soil (III in the figure, hereinafter referred to as “preliminary removal system”). Fourth system: A system for removing harmful substances by blowing fine air bubbles into contaminated soil in a slurry form (IV in the figure, hereinafter referred to as "primary removal system"). Fifth system: a system that removes harmful substances secondarily using an adsorbent that selectively captures harmful substances (V in the figure, hereinafter referred to as “secondary removal system”). Sixth system: A system for concentrating contaminated soil that has been reduced in concentration and slurried through the primary and secondary removal systems (VI in the figure, hereinafter referred to as “concentration system”). Seventh system: A system for reducing dehydration of concentrated contaminated soil using a dehydration device such as a filter press or a belt press (VII in the figure, hereinafter referred to as “dehydration reduction system”). Eighth system: A system for confirming the harmlessness of the drainage obtained through the dehydration reduction system (VIII in the figure, hereinafter referred to as a "harmlessness confirmation system"). Ninth system: a system for containing and processing the residual treated soil obtained by dehydration reduction (IX in the figure, hereinafter referred to as “containment system”). In this system, recirculation is adopted between the element systems, and the processing elements and the processing members such as water or soil are reused.

Hereinafter, each element system (subsystem) will be described in more detail. 1st system (refer to Fig. 1) ... soil extraction system As shown in Fig. 1 I, contaminated soil on the ground or contaminated sediment on the water floor containing dioxins or PCBs (hereinafter collectively referred to as "contaminated soil"). )), A predetermined amount is collected in batches or continuously by excavation or dredging at the site. In the figure, 10 is an excavating machine (backhoe) and 11 is a dredging device. The amount of contaminated soil collected is strictly controlled, escape to other places is suppressed, and a predetermined amount (the whole amount) is sent to the next system. In addition, in this system, in the present system, for the excavation or dredging of contaminated soil, an appropriate construction method according to the characteristics of the soil to be treated and the bottom mud to be treated is selected from a conventionally performed excavation method or dredging method. Further, it is preferable to conduct a pollutant concentration survey prior to the excavation and dredging, to grasp the pollutant concentration distribution of the contaminated soil as detailed as possible, and to excavate and dredge the minimum required contaminated soil based on this data. Reduction of the amount of treated soil by pollution distribution survey leads to efficient treatment, and is not limited to the conventional official survey method, but also uses a simple survey method with a short survey time for bioassays and low cost It is important to reduce the amount of soil to be treated.

Second system (see FIG. 1): water-kneading system The second system comprises a peptizer 1 as shown in II of FIG.
3 is the main component, and has the function of obtaining the fluidity required for the adsorption of harmful substances to be treated in the subsequent process and the prior removal of organic substances containing harmful substances to the contaminated soil sent from the first system. . A known peptizer 13 is used, and fresh water is appropriately added to the contaminated soil from the first system, and these are kneaded to give an appropriate fluidity. Sent to The treatment in this water-kneading system is such that the following pre-adsorption separation treatment or dehydration treatment is smoothly performed, and is omitted if the contaminated soil has appropriate fluidity from the beginning of collection. You. As long as the added water does not contain substances that cause harmful combined pollution, river water, lake water, seawater near the purification site can be used. Since the amount of water to be added changes depending on the water content of the soil to be treated and the characteristics of the soil particles, an optimal amount of water is set in a preliminary laboratory experiment or the like. Usually, water is added so that the water content becomes three times or more the liquid limit of the soil particles.

Third System (See FIG. 1) Preliminary Removal System As shown in III of FIG. 1, this third system is mainly composed of a classifier 14, and the contamination to be treated which has been added and mixed in the second system. It has the function of removing obstacles and coarse particles that hinder the soil in the separation operation in the post-process. As the classifier 14, a known cyclone or vibration screen is used. More specifically, the contaminated soil to be treated, which has been added and kneaded in the second system, is separated and removed in the classifier 14 by the classifier 14, where coarse particles 15 such as coarse particles and obstacles such as dust mixed in the contaminated soil to be treated are separated. .
The separated coarse particles 15 and the coarse particles 15 of the processing obstacles are temporarily stored, and when it is confirmed that no contaminants are attached to the coarse particles 15, the particles are confined together with the reduced-weight treated soil. If contaminants remain in the coarse fraction 15, the contaminants are returned to the second system again. The remaining muddy water from which the coarse particles 15 are separated is adjusted by adding an additive such as a coagulant suitable for the subsequent treatment, and sent to the next step. If it is confirmed from the beginning of collection of the contaminated soil that coarse particles such as coarse particles and obstacles such as dust are not mixed, this system is omitted.

Fourth system (refer to FIG. 2): primary removal system As shown in IV of FIG. 2, the fourth system mainly comprises an oil / water separator 17, and further comprises a mud storage tank 18 and an extraction vessel 19. The main function is to receive mud as soil to be contaminated from the third system, and to perform primary removal of harmful substances by fine bubbles from the mud. More specifically, the oil-water separator 17 uses a bubble separator, receives muddy water formed in the previous third system, and blows fine air bubbles into the muddy water to generate air bubbles having a high concentration of harmful substances on the muddy water surface. Cause. Air bubbles on the surface are scraped off and stored in the extraction container 19, and the remaining muddy water is overflowed and sent to the mud storage tank 18, where it is temporarily stored. After that, it is sent to the next fifth system. Thereby, the harmful substance concentration in the muddy water is greatly reduced. The air bubbles in the extraction container 19 contain harmful substances (such as oil and liquid PCB) and are appropriately processed. The mud storage tank 18 can be omitted as appropriate, and muddy water may be sent directly to the next system.

Fifth System (See FIG. 2) Secondary Removal System As shown in FIG. 2V, the fifth system comprises a dissolved contaminant adsorption tank 21, a sieve separation device 22, a contaminant desorption tank 23, Each of the components of the extraction tank 24 is constituted, and the adsorbent S circulates and moves between the components to remove harmful substances (secondary removal).

First, the adsorbent S will be described. Adsorbent S (see FIGS. 4 and 5) As shown in FIG. 4, the adsorbent S is made of a fiber (fiber with an adsorbent) or cloth coated with, adsorbed or dyed with an adsorbent for selectively adsorbing harmful substances. The main body is formed by folding this long body into multiple layers and storing it in a predetermined container 100. (Container 100) The container 100 is a spherical container having a large number of transmission holes 102, and has two hemispheres 100A, 10A.
OB adopts a structure that can be opened and closed by the pin 104 and cannot be easily opened by the engaging means (not shown) or the like in the closed state. The illustrated example has a net-like structure, and the mesh is a transmission hole 102. The permeation hole 102 has a function of allowing muddy water to pass freely and preventing the adsorbent S from coming out. The container 100 may be made of metal or synthetic resin, and is required to have durability and not to be easily crushed during stirring.

(Fiber with Adsorbent) As the adsorbent in the present embodiment, an adsorbent which selectively adsorbs copper phthalocyanine-based polycyclic aromatics (hereinafter referred to as a polycyclic aromatic adsorbent) is selected. As one example, a copper phthalocyanine-based reactive dye is used. The copper phthalocyanine dye emits a blue color and is dyed by reacting with the OH groups of vegetable fibers such as cotton. This is commercially available as "Blue Cotton". Copper phthalocyanine also dyes amorphous rayon. This is commercially available as "Blue Rayon". "Blue cotton" and "blue rayon" respectively immerse cotton or rayon in an aqueous solution of sodium carbonate. I. Reacture Blue 21 and 70
It is prepared by reacting at 2 ° C. for 2 hours. After dyeing, wash thoroughly with water or an organic solvent and then dry. The fiber dyed with the copper phthalocyanine dye has a function of selectively adsorbing harmful substances such as oils and fats. "Blue rayon" has a higher adsorptivity than "blue cotton".

In order to verify the adsorption effect of blue rayon on dioxins, a test was conducted to remove dioxins in water using blue rayon in the following manner. Test method 1. Test instruments and materials 1) Blue rayon: a commercially available product (manufactured by Daiwa Engineering Co., Ltd.) immersed in an extraction solvent, ultrasonically washed, and dried. 2) Beaker: 1L 3) Water: ultrapure water 4) Dioxin-mixed standard solution 5) CALUX assay test instruments / equipment: 1 set Test method 1) Preparation of test solution: A fixed amount of a dioxin-mixed standard solution was added to a fixed amount of water, and the mixture was thoroughly stirred and mixed to obtain a test solution. 2) Adsorption test: 1 g of blue rayon is placed in 1 L of a test solution placed in a beaker and stirred for 1 hour. Thereafter, the blue rayon is taken out and freeze-dried overnight. 3) Measurement of dioxins: The dioxin concentration of the test solution before and after the adsorption test and the blue rayon after the adsorption test are measured by the CALUX assay. Test Results Two series of adsorption tests were carried out under the same conditions, including a method for extracting dioxins in blue rayon. Table 1 shows the results of each test.

[Table 1] The dioxins in the blue rayon were measured in order to confirm that the dioxins in the test solution were reduced by being adsorbed and removed by the blue rayon. Table 2 shows the results.

[Table 2]

The following is determined by the adsorption removal test. From Table 1, the dioxin concentration in the test solution is
The concentration after extraction from the initial concentration of 22pgTEQ / L is 4.2,
The dioxin concentration in the test solution was remarkably reduced to 4.0 pgTEQ / L or less. From Table 2, the adsorption concentration of blue rayon was 16, 14 pgTEQ / L after adsorption.
And blue rayon shows a remarkable increase in the adsorption concentration of dioxins regardless of the difference in the extraction method and extraction solvent. Therefore, according to the adsorption removal test, it can be seen that blue rayon has a high adsorption ability for dioxins.

FIG. 5 shows another adsorbent S. This adsorber S
Granular activated carbon is used, and many of them are packed in a container 110 of a net-like small bag. This granular activated carbon also exhibits adsorbability to dioxins and PCBs.
Activated carbon has countless fine pores on its surface, and dioxins are trapped in these fine pores. The activated carbon to which harmful substances are attached is incinerated by heat treatment at a high temperature (for example, administration to a high-temperature waste incinerator), or is treated in an inert gas (N2) at about 400 ° C in a required regeneration tower. To decompose dioxins.

Hereinafter, each element of the fifth system in which the adsorbent S circulates and moves will be described in detail. (Dissolved pollutant adsorption tank 21) Dissolved pollutant adsorption tank 2
1 includes a stirring blade 26 driven by a motor M,
The muddy water sent from the previous fourth system is received, and is stirred by the stirring blade 26 together with the container 100 containing the adsorbent S. During the stirring process, the mud passes through the mesh 102 of the container 100 and comes into contact with the adsorbent S inside, and the contaminants in the mud are trapped by the adsorbent S. Therefore, the pollutant concentration of the mud is further reduced and purified. (Screening device 22) When a predetermined stirring action is performed,
The container 100 containing the adsorbent S is transferred to the sieving device 22 together with the muddy water. The container 100 containing the adsorbent S is sieved by the sieving device 22,
It is once stored 27 or sent directly to the contaminant desorption tank 23 in the next step. The muddy water that has passed through the sieving device 22 is sent to the next sixth system. At this time, it is a preferable embodiment to wash the container 100 and thus the absorber S with water. That is, the harmful substances are surely captured by the absorber S, and the captured harmful substances are not washed out by the water washing, but only the excess substances are washed out. Further, the storage 27 can be disposed of as the adsorbent S after the adsorption by heat treatment at a high temperature (for example, administration to a high-temperature waste incinerator) as contaminated waste. (Pollutant Desorption Tank 23) The cleaning liquid is injected into the contaminant desorption tank 23, and the adsorbent S sent through the sieving device 22 into the cleaning liquid is stored in the storage device 10 thereof.
It is thrown in while being confined within 0, and stirred by the stirring blade 28 to wash out contaminants from the adsorbent S. The washed adsorbent S recovers the adsorption performance, and is again in the dissolved contaminant adsorption tank 2
Sent to 1. Thus, the adsorbent S is used in circulation. On the other hand, the solution remaining in the contaminant desorption tank 23 is
When the concentration of the contaminants increases, the contaminants are once transferred to the extraction tank 24. The washing liquid as the extract in the pollutant desorption tank 23 is
For example, a mixture of methanol and a small amount of concentrated ammonia (by volume, 50 to 1) is used. Alternatively, when ultrasonic extraction is performed in the contaminant desorption tank 23, toluene is used as the extract.

Sixth system (refer to FIG. 3): Concentration system As shown in VI of FIG.
0 and the slurry pump 31. More specifically, the concentrating device 30 receives the muddy water sent from the previous fifth system, and supplies the coagulant supply unit 3
The coagulant (PAC, polymer, etc.) from 2 is mixed and stirred by the stirring blade 33. Thereby, muddy water is concentrated. The concentrated muddy water is sent to the next system under high pressure by the slurry pump 31.

Seventh system (see FIGS. 3 and 6): Dehydration and weight reduction system The seventh system includes a dehydrator 35 and a drainage tank 36 as shown in VII of FIG. That is, the dehydrating device 35
Receives the high-pressure mud sent from the slurry pump 31 and dehydrates it with the adsorption filter cloth loaded therein, thereby reducing the amount of the mud having a reduced contamination concentration. FIG. 6 shows the detailed structure of the adsorption filter cloth. Reference numeral 200 denotes one embodiment, in which a filter cloth 204 is sandwiched between both sides of a fiber (fiber with an adsorbent) or a cloth 202 to which an adsorbent for selectively adsorbing oleaginous harmful substances is adsorbed or dyed or a cloth. To form a single adsorption filter cloth, which is used in multiple layers.
The base member 202 has the same configuration as that of the above-described adsorbent S, and its operation and function are similar to those of the adsorbent S. As another embodiment of the adsorption filter cloth 200, one in which a nonwoven fabric made of a fiber in which a copper phthalocyanine-based polycyclic aromatic adsorbent is applied, impregnated or dyed is sandwiched, and further, a nonwoven fabric made by sandwiching activated carbon is sandwiched , Etc. are also adopted as effective ones.

In the seventh system, muddy water is first filtered and dehydrated by the adsorption filter cloth 200 to which the adsorbent is attached, and a thin filter cake film is formed on the surface of the adsorption filter cloth 200. After the filter cake film is formed, most of the harmful substances in the contaminated mud are absorbed and captured by this film layer. The filtered mud is temporarily stored in the drainage tank 36 and sent to the next eighth system (harmlessness confirmation system). Alternatively, it can be sent directly to the eighth system without storage. When the filter cake has grown to a predetermined thickness, the mud feeding is stopped, the filter cake is taken out, and is temporarily stored 37 or sent to the next ninth system (containment system) as it is.

Eighth system (see FIG. 3): Harmlessness confirmation system The eighth system, as shown in VIII of FIG.
The muddy water filtered by the system (concentration system) is used to measure the presence or absence of harmful substances using predetermined measurement means.
Confirm that no harmful substances are contained, then release. If a harmful substance is present, it is returned to the previous system (seventh and fifth systems) according to the degree of its presence. Alternatively, a part thereof is sent to, for example, a water-mixing / kneading system of the second system to be reused. It is effective to reduce the capacity of the storage tank by using a simple measurement method such as bioassay in the measurement in this system.

Ninth system (see FIG. 3). Containment system This ninth system is, as shown by IX in FIG. 3, a treated soil / filter cake that has been dewatered by the previous seventh system (dehydration reduction system). 37, after measuring the amount of harmful substances,
Perform containment processing. Contaminated soil has been sufficiently purified through the previous systems, and contaminated soil is easily contained. That is, even if the soil amount of the treated soil 37 is large, the concentration of the contamination is sufficiently reduced, so that the low-concentration contamination may be caused even by the conventional consolidation method using a consolidation material such as cement. No reduction is achieved. If the disposal amount is small, BCD
It is desirable to disintegrate and detoxify by the method, geomelt method, etc.

In the above-described purification system, a purification facility specific to the present invention, and further a purification member and a purification device are realized. That is, the adsorbent S commonly used in the fifth and seventh systems, and the storage device 100 for storing the adsorbent S
Is a purifying member or purifying device unique to the present invention. Then, in the fifth system, the adsorbent S is stored in the storage device 100 with respect to the contaminated soil which contains the harmful substance of oil and fat and is slurried, and the contaminated soil is stored while the adsorbent S is circulated and moved. It implements equipment for purifying water. In addition, in the seventh system, slurried contaminated soil that contains oily and harmful substances,
The present invention embodies equipment for purifying contaminated soil by dehydration at high pressure using a filter cloth provided with an adsorbent S.

The method for purifying contaminated soil or the like containing oleaginous harmful substances according to the present invention is carried out using the above-mentioned purification system and purification equipment. The purification method of one embodiment is shown. Hereinafter, it shows in order of a process.

(1) In the first system (excavation system), for the contaminated soil on the ground or the contaminated sediment on the water bottom containing PCBs or dioxins, the excavation or dredging is performed on a batch-by-batch or A predetermined amount is continuously collected. The amount of soil collected from contaminated soil or contaminated sediment (hereinafter collectively referred to as “contaminated soil”) is strictly controlled, escape to other places is suppressed, and a predetermined amount (the whole amount) is sent to the next system. Prior to excavation and dredging, conduct a pollutant concentration survey to understand the contaminant concentration distribution of the soil and sediment as detailed as possible, and excavate and dredge the minimum required contaminated soil and sediment based on this data. Is preferred. Reduction of the amount of treated soil by pollution distribution survey leads to efficient treatment, and is not limited to the conventional official survey method, but also uses a simple survey method with a short survey time for bioassays and low cost It is important to reduce the amount of soil to be treated.

(2) Second system (water / kneading system)
In the above, the excavated and dredged soil for purification is mixed with water and kneaded to impart fluidity necessary for adsorption of harmful substances to be treated and prior removal of organic substances including harmful substances. This water-kneading treatment is to ensure that the following pre-adsorption separation treatment and dehydration treatment are carried out smoothly, and it is omitted if the contaminated soil has an appropriate fluidity from the beginning of collection. As long as the added water does not contain substances that cause harmful combined pollution, river water, lake water, seawater near the purification site can be used. Since the amount of water to be added changes depending on the water content of the soil to be treated and the characteristics of the soil particles, an optimal amount of water is set in a preliminary laboratory experiment or the like. Usually, water is added so that the water content becomes three times or more the liquid limit of the soil particles.

(3) Third system (preliminary removal system)
In the above, the water-kneaded contaminated soil to be treated in the previous step is subjected to the following separation treatment to remove obstacles and coarse particles which become obstacles. In this treatment, coarse particles 15 such as coarse particles and dust and other obstacles mixed in the contaminated soil to be treated are separated and removed, but the separated coarse particles and coarse particles 15 of the treatment obstacle are temporarily stored. When it is confirmed that no contaminants are attached to the coarse particles 15, the contaminants are confined together with the reduced soil. If contaminants remain in the coarse fraction 15, the process returns to the previous step of the second system. The remaining muddy water from which the coarse particles 15 are separated is adjusted by adding an additive such as a coagulant suitable for the subsequent treatment, and sent to the next step.

(4) In the fourth system (primary removal system), fine bubbles are sent to the contaminated soil to be treated from the previous water addition / kneading system / preliminary removal system to remove harmful substances in the contaminated soil. Primary removal. That is, the oil / water separator 17 receives the muddy water formed in the previous water-mixing / kneading system / preliminary removing system, and blows fine bubbles into the muddy water to generate air bubbles having a high concentration of harmful substances on the muddy water surface. Let it. Air bubbles on the surface are scraped off and stored in the extraction container 19, and the remaining muddy water is overflowed and sent to the mud storage tank 18, where it is temporarily stored. Thereafter, it is sent to the next step of the fifth system. Thereby, the harmful substance concentration in the muddy water is greatly reduced. The air bubbles in the extraction container 19 contain harmful substances (such as oil and liquid PCB) and are appropriately processed. The mud storage tank 8 can be omitted as appropriate, and muddy water may be sent directly to the next system.

(5) In the fifth system (secondary removal system), following the treatment in the previous primary removal system, secondary removal of harmful substances from the remaining target soil in the primary removal system using an adsorbent. Make That is, if the blowing of fine bubbles in the previous primary removal system is insufficient, an adsorbent is added and mixed to reduce the concentration of harmful substances. Adsorbents that adsorb oil etc. can also be used without using adsorbents that use adsorbents that selectively adsorb harmful substances,
Such a general adsorbent adsorbs other organic substances and the like contained in contaminated soil and contaminated sediment, so that the adsorption characteristics deteriorate in a short period of time, which is a problem. When it is confirmed that the adsorption characteristics of the adsorbent have decreased, the adsorbent is separated with a sieve or the like and replaced with a new adsorbent. The adsorbent that has been adsorbed is disposed of as contaminated waste by heat treatment or the like. The mud with reduced contaminant concentration is sent to the next dehydration and weight reduction process.

(6) In the sixth system (concentration system), the required concentration treatment is performed on the muddy water sent from the fifth system in the preceding process. That is, the concentration device 30
Receives the muddy water sent from the previous fifth system, and receives the flocculant (PAC,
Polymer, etc.) and are stirred by the stirring blade 33. Thereby, muddy water is coagulated. The condensed muddy water is sent to the next system under high pressure by the slurry pump 31.

(7) Seventh system (dehydration reduction system)
In the above, the muddy water sent from the preceding system is dewatered and reduced under a predetermined pressure by using a dewatering device 35 such as a filter press or a belt press using an adsorber. That is, the dewatering device 35 receives the high-pressure mud sent from the preceding system, dehydrates it using the adsorption filter cloth 200 loaded therein, and performs a reduction process on the mud having a reduced contamination concentration. The adsorbent filter cloth 200 is formed by sandwiching a filter cloth 204 from both sides of a fiber (fiber with an adsorbent) or a cloth to which an adsorbent for selectively adsorbing harmful substances is applied, attached or dyed, or a cloth. , And the filter cloth is laminated and used. The substrate 202 is made of the adsorbent S
Is the same as More specifically, the muddy water is first filtered and dehydrated by an adsorption filter cloth 200 to which an adsorbent is attached,
A thin filter cake film is formed on the surface of the adsorption filter cloth 200. After the filter cake film is formed, most of the harmful substances in the contaminated mud are absorbed and captured by this film layer. The filtered mud is temporarily stored in the drainage tank 36 and sent to the next eighth system (harmlessness confirmation system). Alternatively, it can be sent directly to the eighth system without storage. When the filter cake has grown to a predetermined thickness, the mud feeding is stopped, the filter cake is taken out, and is temporarily stored or sent to the next ninth system (containment system) as it is. In addition, only the harmful substance which passed through the filter cake for a short time until the filter cake thin film was formed is adsorbed by the filter cloth to which the adsorbent was attached and dyed.

(8) Eighth system (harmlessness confirmation system)
In the above, the presence or absence of harmful substances is measured with predetermined measuring means on the muddy water filtered by the previous seventh system (condensing system), and it is confirmed that no harmful substances are contained. If there are harmful substances, the previous system (seventh and fifth systems) according to the degree of their presence
Is returned to. Alternatively, a part thereof is sent to, for example, a water-mixing / kneading system of the second system to be reused. It is effective to reduce the capacity of the storage tank by using a simple measurement method such as bioassay in the measurement in this system.

(9) In the ninth system (containment system), the treated soil / filter cake 37 that has been dehydrated in the previous seventh system (dehydration reduction system) is subjected to containment processing by predetermined means. The treated soil / filter cake 37 has a sufficiently reduced concentration of contaminants, and is mixed with cement, solidified, and buried in a predetermined place. Even if the amount of the treated soil / filter cake 37 becomes large, the contamination concentration is sufficiently reduced, so that the low-contamination contamination can be achieved by the conventional consolidation method using a consolidation material such as cement. Thus, the reduction disposal is achieved without fear. When the disposal amount is small, it is desirable to disintegrate and detoxify by BCD method, geomelt method or the like.

Since the method for purifying contaminated soil or the like containing oily and harmful substances according to the present embodiment is performed by the above-described steps, the following effects are exerted and specific effects are obtained. Process
In step (4), fine bubbles are sent to remove harmful substances in the contaminated soil, and the concentration of harmful substances in mud is greatly reduced.In step (5), an adsorbent that selectively adsorbs harmful substances is used. Since the secondary removal of harmful substances is performed by the adsorbents attached, the harmful substances are surely removed from the soil to be contaminated. In addition, the processing load on the adsorbent in the step (5) is reduced, and not only the removal rate is dramatically improved, but also the adsorption capacity is maintained for a long time. In addition, the adsorbent is not directly disposed of by heat treatment or the like, but can be reused after cleaning contaminants, thereby improving efficiency. Furthermore, in step (7), a filter cloth using an adsorbent impregnated with an adsorbent that selectively adsorbs harmful substances is used to capture contaminants in contaminated soil sent from the previous step under high pressure. As a result, contaminated soil is reliably purified. In this way, the concentration of the contaminants in the contaminated soil is eventually sufficiently reduced, and the remaining soil can be safely treated by the consolidation method. Therefore, a treatment method that can cope with a large amount of residual soil has been established. In the case of the polluted sediment predominant in the silt component, most of the main components are contained in the drainage water, so the residual soil is small, and a method of treating a large amount of the sludge sediment can be established.

The method for purifying contaminated soil or the like containing oily and harmful substances of the present invention is not limited to the purification method described in the above embodiment, but may employ other embodiments. In the above step (1), if the collected contaminated soil has sufficient slurry properties (fluidity) from the beginning and does not contain coarse particles,
The steps (2) and (3) are omitted. Step (4) above is omitted as necessary. Therefore, only the steps (1) and (5) constitute a purification method of another embodiment. Step (6) above is omitted as appropriate. Therefore, only the steps (1), (5) and (7) constitute a purification method of still another embodiment. Further, only the steps (1) and (7) constitute a purification method of still another embodiment. The steps (8) and (9) are appropriately performed. That is, in the previous embodiment, the description has been mainly directed to the bottom sediment, but in soil mainly containing sandy components, (6)
Steps (7) and (7) are omitted. In addition, the step (1) is not limited to the direct collection of contaminated soil, but may be performed on contaminated soil that has already been collected. Further, the waste is not limited to the contaminated soil, and may be a waste containing a contaminant in the same mode, and may be slurried or slurried.

The present invention is not limited to the above embodiment, and various design changes can be made within the scope of the basic technical concept of the present invention.

[0045]

According to the method for purifying contaminated soil or the like containing oily and harmful substances according to the present invention, the contaminant is adsorbed by the adsorbent introduced into the slurried contaminated soil, and the contaminated soil is removed. Because it separates, the treatment of pollutants can be performed intensively, and safe and efficient treatment can be achieved.The remaining contaminated soil will be of sufficiently low concentration, so that its containment is easy and convenient. It is a purification process that can be performed safely and is therefore applicable to large amounts of contaminated soil. Also,
If the contaminated soil passes through a filtration treatment of silt or the like, the remaining soil is small and the treatment is easy, and therefore, a wide area of contaminated sediment can be handled.

[Brief description of the drawings]

FIG. 1 is a configuration diagram of first to third systems of a purification system for implementing a purification method of the present invention.

FIG. 2 is a configuration diagram of fourth to fifth systems.

FIG. 3 is a configuration diagram of sixth to ninth systems.

FIG. 4 is a configuration diagram of an accommodating container.

FIG. 5 is a configuration diagram of another container with a suction element.

FIG. 6 is a configuration diagram of an adsorption filter cloth.

[Explanation of symbols]

S: Adsorber, 13: Peptizer, 14: Classifier, 17:
Oil / water separator, 18: storage tank, 21: dissolved contaminant adsorption tank, 22: sieving apparatus, 23: contaminant desorption tank,
Reference numeral 30: concentrating device, 31: slurry pump, 35: dehydrating device, 36: drainage tank, 100, 110: container, 102:
Permeation hole, 200 ... adsorption filter cloth

──────────────────────────────────────────────────続 き Continued on the front page (51) Int.Cl. ⁷ Identification symbol FI Theme coat ゛ (Reference) B01J 20/22 B01J 20/34 G 4D059 20/34 B09B 3/00 301E 4G066 B09B 3/00 301 301S C02F 1 / 28 A B09C 1/02 11/00 C 1/08 Z C02F 1/28 101Z 11/00 11/12 C B09B 5/00 ZABS 101 3/00 304K 11/12 (72) Inventor Koji Ohkita Tokyo 2-3-11 Kanda Surugadai, Chiyoda-ku, Japan Konoike-gumi Co., Ltd. No. 18 No. 2 F term (reference) 2E191 BA12 BA13 BB01 BC01 BC05 BD00 BD01 4D004 AA41 AB06 AB07 CA13 CA45 CA47 CC13 CC15 4D017 AA01 BA05 CA11 CB03 CB10 DA07 DB02 E A03 EA07 4D019 AA03 BA12 BB02 BB03 BC05 4D024 AA08 AB06 AB11 BA02 BA16 BB01 BB02 BC04 CA01 CA06 DA01 DA02 DA07 DA10 DB03 DB08 DB18 DB29 DB30 4D059 AA09 AA18 BE10 BE15 BE16 BE55 BE56 BF15 BF17 BG00 B03 DA03 AC02C AC11C BA03 BA12 BA16 CA33 DA07 DA15 DA20 FA12 GA11

Claims (19)

[Claims] 1. A contaminated soil obtained by slurping contaminated soil or the like containing an oily harmful substance and slurrying a permeable container containing an adsorbent for selectively adsorbing the oily harmful substance. Mixed into the soil, the harmful substance contained in the contaminated soil is adsorbed by the adsorbent, and thereafter, the storage device is separated from the soil to be purified. To clean contaminated soil. 2. A contaminated soil obtained by slurping contaminated soil or the like containing an oily harmful substance, and slurrying a permeable container containing an adsorbent for selectively adsorbing the oily harmful substance. Mixed into the contaminated soil, the harmful substances contained in the contaminated soil are adsorbed by the adsorbent, and then the storage device is separated from the soil for purification, and the remaining soil for purification is A method for purifying contaminated soil or the like containing harmful substances, wherein dehydration is performed using a filter cloth containing an adsorbent having the same function as the adsorbent. 3. The contaminated soil or the like according to claim 1, wherein the contaminated soil or the like containing an oily harmful substance is collected, and the contaminated soil is slurried. A method for purifying contaminated soil or the like containing harmful substances, which comprises adding a treatment for primary removal of harmful substances by fine bubbles to a target soil. 4. The adsorbent according to any one of claims 1 to 3, wherein the adsorbent is made of a fiber in which an adsorbent for selectively adsorbing oleaginous harmful substances is adsorbed on fibers or granular activated carbon. A method for purifying contaminated soil or the like containing harmful substances, characterized in that: 5. The method according to claim 4, wherein the adsorbent applied to the adsorbent is a copper phthalocyanine polycyclic aromatic adsorbent. 6. The adsorbent according to any one of claims 1 to 5, wherein the adsorbent having adsorbed the harmful substance is separated from the soil to be decontaminated and then treated while adsorbing the harmful substance, or separated from the soil to be decontaminated. A method for purifying contaminated soil or the like containing harmful substances, wherein the harmful substances are washed and then reused. 7. The method for purifying contaminated soil or the like containing harmful substances according to any one of claims 1 to 6, wherein the contaminated soil is bottom sediment on a water floor. 8. A permeable container containing an adsorbent for selectively adsorbing oleaginous harmful substances to contaminated soil or the like which contains oleaginous harmful substances and is slurried is made into the slurry. Mixing and agitating the contaminated soil, adsorbing the harmful substance contained in the contaminated soil to the adsorbent, and separating the storage device from the object of purification of contaminants. Soil purification equipment. 9. A filter cloth provided with an adsorbent for selectively adsorbing oleaginous harmful substances to a slurry of contaminated soil or the like containing oily harmful substances and contained in said contaminated soil. A facility for purifying contaminated soil or the like containing a harmful substance, wherein the harmful substance is adsorbed on the adsorbent and dehydrated at a high pressure. 10. The method according to claim 8, wherein
The adsorbent is selected from fibers with an adsorbent that selectively adsorbs oleaginous harmful substances, or granular activated carbon. Purification of contaminated soil, etc. containing harmful substances. Facility. 11. A purification system for contaminated soil and the like containing oily and harmful substances, characterized by comprising the following element systems: (1) Contaminated soil and contaminated sediment containing oily and harmful substances Drilling and dredging system. (2) A system in which the excavated and dredged soil is slurried by water mixing. (3) A system that removes obstacles and coarse particles contained in the slurried contaminated soil. (4) A system for primary removal of harmful substances using microbubbles from polluted soil in slurry. (5) To the residual contaminated soil in the primary removal, the harmful substance contained in the contaminated soil is adsorbed to the adsorbent by an adsorbent for selectively adsorbing oleaginous harmful substances, and the secondary removal of harmful substances is performed. (6) A system that concentrates contaminated soil remaining after secondary removal. (7) Concentrated secondary contaminated residual soil, contained in the contaminated soil by a filter cloth equipped with an adsorbent impregnated with fibers, an adsorbent that selectively adsorbs oily harmful substances A system in which the harmful substances are adsorbed on the adsorbent and dehydrated at high pressure. (8) A system to confirm the harmlessness of the drainage of the previous (7) system. (9) Dewatering and weight reduction treatment of the previous (7) system. 12. A purification system for contaminated soil or the like containing oily and harmful substances, characterized by comprising at least the following element systems: (1) Contaminated soil and polluted bottom containing oily and harmful substances A system for excavating and dredging mud. (2) A system in which the excavated and dredged soil is slurried by water mixing. (3) To the slurry of the soil to be contaminated, the harmful substances contained in the contaminated soil are adsorbed to the adsorbent by an adsorbent that selectively adsorbs oleaginous harmful substances to remove the harmful substances. Eggplant system. 13. A purification system for contaminated soil or the like containing oily and harmful substances, characterized by comprising at least the following element systems: (1) Contaminated soil and polluted bottom containing oily and harmful substances A system for excavating and dredging mud. (2) A system in which the excavated and dredged soil is slurried by water mixing. (3) The filter cloth equipped with an adsorbent for selectively adsorbing oleaginous harmful substances to the slurried contaminated target soil,
A system in which harmful substances contained in the contaminated soil are adsorbed on the adsorbent and dehydrated at high pressure. 14. A purification system for contaminated soil or the like containing oily and harmful substances, characterized by comprising at least the following element systems: (1) Contaminated soil and contaminated bottom containing oily and harmful substances A system for excavating and dredging mud. (2) A system in which the excavated and dredged soil is slurried by water mixing. (3) To the slurry of the soil to be contaminated, the harmful substances contained in the contaminated soil are adsorbed to the adsorbent by an adsorbent that selectively adsorbs oleaginous harmful substances to remove the harmful substances. (4) A filter cloth provided with an adsorbent for selectively adsorbing oleaginous harmful substances with respect to the remaining contaminated soil of the system of (3), whereby harmful substances contained in the contaminated soil are removed. A system for adsorbing the adsorbent and dehydrating at a high pressure. 15. A system according to claim 12, wherein a primary removal of harmful substances by fine air bubbles is performed between the systems (2) and (3) for the slurried contaminated soil. A system for purifying contaminated soil containing oleaginous harmful substances. 16. The adsorbent according to any one of claims 12 to 15, wherein the adsorbent is made of a fiber having an adsorbent for selectively adsorbing oleaginous harmful substances, or granular activated carbon. A purification system for contaminated soil containing oily and toxic substances. 17. An adsorbent for mixing and agitating into a slurry of contaminated soil, adsorbing oleaginous harmful substances contained in the contaminated soil, and selectively adsorbing oleaginous harmful substances. Transparent container. 18. An adsorbent according to claim 17, wherein an adsorbent in which a sorbent for selectively adsorbing oleaginous harmful substances is adhered to the fiber, or an adsorbent in which granular activated carbon is selected is accommodated. Transparent container. 19. The permeable container according to claim 18, wherein the adsorbent applied to the adsorber contains an adsorbent which is a copper phthalocyanine-based polycyclic aromatic adsorbent.