JP2003245650A - Soil cleaning method and apparatus therefor - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a soil cleaning method and an apparatus for the treatment capable of efficiently treating soil even when there are many fine particles in the soil. <P>SOLUTION: Based on the particle size r, the bulk density ρ of the soil and the concentration c of a harmful substance (particularly, a viscous substance such as oil or the like) in the soil, the flow velocity v of a cleaning solution for cleaning the soil is controlled to be a prescribed value and at the same time, if the turbidity d of the cleaning solution exceeds a standardized value, the flow velocity v of the cleaning solution is controlled (lowered) so as to keep the turbidity d not higher than the standardized value and if an abnormal incident occurs in a cleaning tank 11, the flow velocity v of the cleaning solution is controlled (lowered) so as to suppress the abnormal incident. <P>COPYRIGHT: (C)2003,JPO

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a soil purification method and apparatus for purifying the soil by circulating a purification liquid for washing the soil in the soil polluted with various harmful substances.

[0002]

2. Description of the Related Art In recent years, soil pollution due to leakage of domestic effluent, effluent from factories, offices, etc., and soil contaminated with chemical substances that could not be naturally decomposed due to soil pollution such as factory site, Groundwater has increased, resulting in serious impacts on the soil environment as an ecosystem and social infrastructure. Therefore, various methods for purifying such contaminated soil and groundwater have been proposed. However, there are no effective treatment methods for halogenated compounds such as polychlorinated biphenyls (PCBs) and dioxins, which are persistent organic pollutants, and polycyclic aromatic oils, and measures such as incineration and containment are not available. This is the current situation.

[0003] The incineration treatment that has been generally performed conventionally is the incineration of a rotary kiln or the like of soil contaminated with various harmful substances such as halogen compounds and oils which are persistent organic pollutants as described above. The equipment is incinerated in a high temperature atmosphere to incinerate and decompose various harmful substances contained in contaminated soil, and return it to the environment as purified soil. Further, the gas discharged by decomposing various harmful substances in this incineration facility is rendered harmless, and is discharged to the atmosphere as exhaust gas together with the combustion gas.

However, such a large-scale incineration facility has a large energy cost for treating a large amount of contaminated soil, and there is a possibility that waste may be handled due to alteration of the soil after treatment. Therefore, it may be difficult to reuse. On the other hand, the containment treatment of contaminated soil described above is not essentially a purification measure for contaminated soil,
It is a passive method of simply blocking from the natural world.
Therefore, there is a demand for an economically advantageous soil treatment method for appropriately purifying soil contaminated with the various harmful substances and returning it to the natural world.

Therefore, for example, in the soil purification method disclosed in Japanese Patent Laid-Open No. 11-5075, a water-soluble organic solvent is added to soil contaminated with oil and mixed and stirred to extract oil in the soil. Solid-liquid separation, by removing the liquid in the soil by removing the liquid from the soil in a state of being mixed with an organic solvent, while recovering the organic solvent by distilling the liquid produced by solid-liquid separation, While separating and treating oil, air is sent to the washed soil to remove the organic solvent from the soil, and the air is cooled to condense and recover the organic solvent. Therefore, the oil content in the soil can be remarkably reduced, and the soil can be properly purified and reused.

[0006]

However, in the conventional soil remediation method as described above, when it is attempted to treat soil with many fine particles such as sediment in rivers, etc. In some cases, a fine particle layer was formed along with the flow, and the solid-liquid separation efficiency was reduced, resulting in poor processing efficiency.

In view of the above, it is an object of the present invention to provide a soil remediation method and an apparatus therefor capable of efficiently treating soil having a large amount of fine particles.

[0008]

[Means for Solving the Problems] A soil purification method according to the first aspect of the invention for solving the above-mentioned problems is a method for circulating a cleaning liquid for cleaning the soil in soil contaminated with harmful substances. It is characterized in that the flow rate of the cleaning liquid is controlled so as to suppress the flow of fine particles in the soil due to the circulation of the cleaning liquid.

The soil purification method according to the second aspect of the present invention is the method of the first aspect, wherein the flow rate of the purification liquid has a preset value based on the particle size and bulk density of the soil. It is characterized by controlling the flow rate of the liquid.

The soil purification method according to the third aspect of the present invention is the method of the first aspect, wherein the flow rate of the purification liquid is preset based on the particle size and bulk density of the soil and the concentration of the harmful substance in the soil. It is characterized in that the flow velocity of the purifying liquid is controlled so as to reach the set value.

The soil purification method according to a fourth aspect of the present invention is the soil purification method according to any one of the first to third aspects, wherein when the turbidity of the cleaning liquid exceeds a specified value, the turbidity is the specified value. It is characterized in that the flow rate of the purification liquid is controlled so as to be as follows.

The soil purification method according to a fifth aspect of the present invention is the method of cleaning a soil according to any one of the first to fourth aspects, wherein the purification liquid is an organic solvent and the harmful substance is a residual organic pollutant. It is characterized by being a harmful organic substance containing a compound or oil.

A soil purification method according to a sixth aspect of the present invention is characterized in that, in any one of the first to fourth aspects, the purification liquid is water and the harmful substance is a water-soluble harmful inorganic substance. And

A soil purification method according to a seventh aspect is the soil purification method according to any one of the first to fourth aspects, wherein the purification liquid is an alkaline liquid and the harmful substance is an alkali-soluble harmful inorganic substance. Is characterized by.

The soil purification method according to an eighth aspect of the invention is the soil purification method according to any one of the first to fourth aspects, wherein the purification liquid is an acidic liquid and the harmful substance is an acid-soluble harmful inorganic substance. Is characterized by.

A soil purifying apparatus according to a ninth aspect of the invention for solving the above-mentioned problems is a cleaning tank for holding soil contaminated with harmful substances, and the soil in the cleaning tank. Purification liquid circulation means for circulating the purification liquid to be washed, and purification for controlling the purification liquid circulation means so as to suppress the flow of fine particles in the soil accompanying the circulation of the purification liquid And a liquid flow rate control means.

A soil purifying apparatus according to a tenth aspect of the present invention is the soil purifying device according to the ninth aspect, wherein the cleaning liquid flow rate control means measures the particle diameter of the soil, and the soil in the cleaning tank. Bulk density measuring means for measuring the bulk density, and based on the measurement results by the particle size measuring means and the bulk density measuring means, the purification liquid flow so that the flow velocity of the purification liquid becomes a preset value. And a control means main body for controlling the means.

The soil purification apparatus according to the tenth invention is
In a ninth aspect of the invention, the purification liquid flow rate control means is
Particle size measuring means for measuring the particle size of the soil, bulk density measuring means for measuring the bulk density of the soil in the washing tank, and harmful substance concentration measuring means for measuring the concentration of the harmful substance in the soil And, based on the measurement results by the particle size measuring means, the bulk density measuring means and the harmful substance concentration measuring means,
And a control means main body for controlling the purification liquid flow means so that the flow velocity of the purification liquid becomes a preset value.

A soil purifying apparatus according to the twelfth invention is
In any one of the ninth to tenth inventions, the purified liquid flow rate control means includes a turbidity measurement means for measuring the turbidity of the purified liquid, and the control means body is the turbidity measurement means. When the turbidity exceeds a specified value based on the measurement result in 1., the purifying liquid circulating means is controlled so that the turbidity becomes equal to or less than the specified value.

A soil purifying apparatus according to the thirteenth invention is
In any one of the ninth to twelfth inventions, the purified liquid flow rate control means includes a cleaning tank inside observation means for observing a state inside the cleaning tank, and the control means main body is inside the cleaning tank. When an abnormality occurs in the cleaning tank based on the observation result by the observation means, the cleaning liquid flow means is controlled so as to suppress the abnormality.

[0021]

BEST MODE FOR CARRYING OUT THE INVENTION Embodiments of a soil purification method and an apparatus therefor according to the present invention will be described with reference to FIGS. FIG. 1 is a schematic configuration diagram of a soil purification device, FIG. 2 is an explanatory diagram of a soil cleaning method, and FIG. 3 is a schematic structural diagram of a cleaning tank. The present invention is not limited to the embodiments below.

As shown in FIG. 1, it is polluted with harmful organic substances such as halogen compounds and polycyclic aromatic oils which are persistent organic pollutants such as polychlorinated biphenyls (PCBs) and dioxins. The cleaning tank 11 for carrying in and purifying soil contaminated with various harmful substances such as heavy metals such as mercury and lead and harmful inorganic substances such as cyanides is portable. And a large number of washing tanks 11
Is transported to the soil treatment site for use.

The tank unit 12 is a refined solvent tank 1
3, discharge solvent tanks 14 and 15, and cleaning liquid tank 16
And have. The refined solvent tank 13 stores a solvent for extracting harmful organic substances contained in the soil, and has a refined solvent supply pump 17 in the supply pipe 1.
It is connected to each cleaning tank 11 via 8. On the other hand, the discharged solvent tanks 14 and 15 store the solvent containing the harmful organic substance extracted from the soil in the cleaning tank 11, and through the discharge pipe 21 having the operation valve 19 and the extraction solvent discharge pump 20. Are connected to each cleaning tank 11.
A circulation pipe 24 having an operation valve 22 and a circulation pump 23 is connected between the supply pipe 17 and the discharge pipe 21.

Therefore, the operation valve 19 is opened and the operation valve 22 is opened.
When the refined solvent pump 17 is driven in the closed state,
The solvent in the purified solvent tank 13 can be supplied to each cleaning tank 11 through the supply pipe 18, and when the extraction solvent discharge pump 19 is driven, the extraction solvent in each cleaning tank 11 is discharged through the discharge pipe 21. Can be discharged to each of the discharged solvent tanks 14 and 15. On the other hand, when the circulation pump 23 is driven in a state where the operation valve 19 is closed and the operation valve 22 is opened, the solvent can be circulated and discharged from the cleaning tank 11 through the circulation pipe 24.

The cleaning liquid tank 16 stores a cleaning liquid for dissolving and extracting or decomposing the harmful inorganic substances contained in the soil, and each cleaning tank 11 is provided via a supply pipe 26 having a cleaning liquid supply pump 25. Are linked to. A discharge pipe 29 having an operation valve 27 and a cleaning liquid discharge pump 28 is connected to each cleaning tank 11. A circulation pipe 32 having an operation valve 30 and a circulation pump 31 is connected between the supply pipe 26 and the discharge pipe 29.

Therefore, the operation valve 27 is opened and the operation valve 30 is opened.
When the cleaning liquid pump 25 is driven in the closed state, the cleaning liquid in the cleaning liquid tank 16 can be supplied to each cleaning tank 11 through the supply pipe 26, and when the cleaning liquid discharge pump 28 is driven, each cleaning tank The extraction cleaning liquid in 11 can be discharged through the discharge pipe 29. On the other hand, when the circulation pump 31 is driven in a state where the operation valve 27 is closed and the operation valve 30 is opened, the circulation pipe 3 is connected to the cleaning tank 11.
By 2, the cleaning liquid can be circulated and discharged.

A concentration sensor 33 for detecting the concentration of harmful organic substances contained in the extraction solvent is attached to the discharge pipe 21, while a concentration sensor 33 for detecting the concentration of harmful inorganic substances contained in the extraction cleaning liquid is attached to the discharge pipe 29. The sensor 34 is attached. In this case, it is desirable to provide a plurality of sensors that detect the concentration with high accuracy according to the types of harmful organic substances and harmful inorganic substances.

The purification unit 35 removes harmful organic substances from the extraction solvent discharged from the cleaning tank 11 and stored in the discharge solvent tanks 14 and 15 for purification.
And a cleaning liquid purifying device 37 that removes and purifies harmful inorganic substances from the extracted cleaning liquid discharged from the cleaning tank 11, and a soil from which harmful organic substances or harmful inorganic substances have been removed by sucking gas from each cleaning tank 11. On the other hand, it has a drying device 38 for removing the residual solvent or cleaning liquid and drying.

The solvent refining device 36 is a distillation device 42 in which a strainer 39 for removing coarse particles such as sand, an oil strainer 40 for removing oil and fat, and a boiler 41 are connected.
It consists of and. Then, the discharged solvent tank 14,
15 and the strainer 39 are connected by a transfer pipe 44 having a transfer pump 43. On the other hand, the distillation device 42 and the purified solvent tank 13 are connected by a return pipe 46. In addition, the strainer 39, the oil strainer 40,
An organic substance treatment device 48 is connected to the distillation device 42 via an organic substance discharge pipe 47.

Therefore, when the extraction solvent in the discharge solvent tanks 14 and 15 is sent to the solvent refining device 36 through the transfer pipe 44 by driving the transfer pump 43, the harmful organic substances are removed from the extraction solvent and purified. The extracted solvent thus extracted can be returned to the purified solvent tank 13 through the return pipe 46. On the other hand, the harmful organic substances removed by the solvent refining device 36 are passed through the organic substance discharge pipe 47 to the organic substance treatment device 4
8 where it can be detoxified.

The cleaning liquid purifying device 37 comprises a sand filtration tower 49 and a resin adsorption tower 50. The downstream end of the cleaning liquid discharge pipe 29 is connected to the sand filtration tower 49, and the resin adsorption tower 50 and the cleaning liquid tank are connected. 16 is connected by a return pipe 51, and an inorganic substance processing device 53 is connected to the sand filtration column 49 and the resin adsorption column 50 via an inorganic substance discharge pipe 52.

Therefore, when the cleaning liquid discharge pump 28 is driven and the extraction cleaning liquid is sent from each cleaning tank 11 to the cleaning liquid purifying device 37 through the discharge pipe 29, the harmful inorganic substances are removed from the cleaning liquid and purified. The cleaning liquid can be returned to the cleaning liquid tank 16 through the return pipe 51. On the other hand, the harmful inorganic substance removed by the cleaning liquid purification device 37 is passed through the inorganic substance discharge pipe 52 to the inorganic substance treatment device 53.
Sent to and can be detoxified here.

Further, the drying device 38 includes a knockout pot 54 for collecting the mist of the solvent in the air discharged from the cleaning tank 11, a heat exchanger 55 for cooling the air and collecting the vaporized solvent, It comprises a blower 56 and an activated carbon tower 57 for adsorbing and removing the vapor of the solvent. Cleaning tank 1
1 is a knockout pot 5 through the air exhaust pipe 58.
4, the activated carbon tower 57 is connected and connected to the cleaning tank 11 via an air supply pipe 59. Further, the knockout pot 54 and the heat exchanger 55 are the solvent return pump 6
It is connected to the discharged solvent tank 15 through a return pipe 65 having a number 4.

Therefore, the blower 56 is operated to activate the cleaning tank 11
When the air inside is sucked, the air is knocked out of the knockout pot 5.
The mist of the solvent is recovered in 4 and the heat exchanger 5
Cooled in 5, the gaseous solvent is recovered as a liquid,
Furthermore, the solvent remaining in the cleaning tank 11 can be evaporated and removed from the soil by being purified by the activated carbon tower 57 and supplied to the cleaning tank 11.

A boiler unit 61, a cooling unit 62, a compressor unit 63 and the like are provided as the utility unit 60. The boiler unit 61 is for heating the air supplied to the cleaning tank 11 as needed, and the cooling unit 62 is for the heat exchanger 55.
In order to cool the air discharged from the cleaning tank 11 to cool the temperature-increased cooling water, the compressor unit 63 is for operating various pumps.

By the way, a cleaning liquid for washing soil polluted with harmful substances, more specifically, an extraction solvent for extracting the harmful organic substances contained in the soil and the harmful inorganic substances contained in the soil. It is necessary to set the type of the cleaning solution for dissolution extraction or decomposition cleaning based on the concentration of harmful organic substances and harmful inorganic substances in the soil, which is obtained by conducting a soil contamination survey in advance.

In the present embodiment, as shown in FIG. 2, a hydrophilic solvent such as alcohol is used as an extraction solvent (organic solvent), and water or an alkaline liquid (for example, alcohol) is used as a cleaning liquid.
NaOH) and acidic solutions (eg H ₂ SO ₄ ) are used. Specifically, while the refined solvent tank 13 that stores alcohol is provided, a water tank 16a that stores water, an alkaline liquid tank 16b that stores an alkaline liquid, and an acidic liquid tank 16c that stores an acidic liquid are provided.

The cleaning tank 11 is, as shown in FIG.
A tank body 71 having an opening at the top to hold soil, and a tank body 7
1 is provided with a lid 72 for closing the upper opening, and supply ports 73 and 74 are formed in the upper and lower parts and a discharge port 75 is formed in the lower part. In addition, a lattice-shaped support portion 76 is integrally formed in the tank main body 71 and is located below.
A filtration filter 77 is laid on the support portion 76, and the support portion 76, the filtration filter 77 and the like constitute a filter means in the present embodiment. And
The supply pipe 18 branches and is connected to the upper and lower supply ports 73 and 74 via the operation valves 78 and 79, while the discharge pipe 21 is connected to the discharge port 75.

Further, in the vicinity of the cleaning tank 11, there is mounted a slicing device 66 for uniformly sowing the soil inside the cleaning tank 11. The planting device 66 includes a particle size measuring device 81 which is a particle size measuring means for measuring the particle size of soil, and a harmful substance concentration measurement for measuring the concentration of harmful substances such as harmful organic substances and harmful inorganic substances in the soil. Measuring instrument for harmful substance concentration 82
And are provided respectively. A weight measuring device 83, which is a weight measuring means for measuring the weight of the soil in the cleaning tank 11, is disposed below the cleaning tank 11.

At the upper part of the inner wall surface of the cleaning tank 11, a stacking height measuring device 84 which is a stacking height measuring means for measuring the stacking height of the soil inside the cleaning tank 11, and the inside of the cleaning tank 11 And a CCD camera 85 which is an observation means in the cleaning tank for observing the above state. The discharge pipe 2
In the vicinity of the discharge port 75 of No. 1, a turbidity measuring device 86, which is a turbidity measuring means for measuring the turbidity of the extraction solvent, and a flowmeter 87 for measuring the flow rate of the extraction solvent are provided. .

Each of the measuring instruments 81 to 87 is connected to an input portion of a control device 88 which is a control means main body. The output of the control device 88 is the pump 17, 2
0 and 23 respectively, and the control device 88
Controls the pumps 17, 20, and 23, respectively, based on the signals from the measuring instruments 81 to 87 (details will be described later). Further, in FIG. 3, 89 is a monitor.

Although the extraction solvent supply / discharge equipment has been described here, the cleaning agent supply / discharge equipment has the same structure.

In this embodiment, the tank unit 12 and the pumps 17, 20, 23, 2 are
5, 28, 31 and the pipes 18, 21, 24, 26, 2
9. The operation valves 19, 22, 27, 30, 78, 79 and the like constitute a cleaning liquid circulating means for circulating a cleaning liquid for cleaning the soil in the soil in the cleaning tank 11, and the weight measuring device 8
3, the stacking height measuring device 84 and the like constitute a bulk density measuring device for measuring the bulk density of the soil in the cleaning tank 11, and the bulk density measuring device, the particle size measuring device 81, the harmful substance concentration measuring device 8
2, CCD camera 85, turbidity meter 86, flow meter 87,
The control device 88, the monitor 89 and the like constitute a purified liquid flow rate control means.

Next, a soil purification method using the soil purification apparatus of the present embodiment will be described.

First, the state of contamination on the site of soil purification treatment is investigated in advance, necessary equipment, treatment agents, etc. are prepared, various devices are transported to the site and assembled, and a purification facility is installed. The number of cleaning tanks 11 to be installed is set according to the size of the treatment site, the amount of soil to be purified, and the like.

Then, after the equipment for purifying the soil is installed, as shown in FIG. 3, first, a predetermined amount of soil is put into the tank body 71 of each cleaning tank 11 by the seeding device 66. At this time, the particle size measuring device 81 measures the particle size r of the soil, and the harmful substance concentration measuring device 81 measures the concentration c of the harmful substances such as harmful organic substances and harmful inorganic substances in the soil. Is transmitted to the control device 88. Furthermore, the weight measuring device 83 measures the weight w of the soil sowed out in the tank body 71 of the cleaning tank 11, and the stacking height measuring device 84 measures the stacking height h of the soil. Is transmitted to the control device 88.

The control device 88 calculates the bulk density ρ of the soil in the tank body 71 from the weight w and the stacking height h of the soil in the tank body 71 so that the fine particles in the soil do not flow. , The bulk density ρ, the particle size r, and the concentration c of the harmful substance (particularly, viscous substances such as oil) at a preset flow rate v, and the extraction solvent (alcohol) in the purification solvent tank 13 Via the supply pipe 18
The refining solvent supply pump 17 is controlled so as to supply the purified solvent.

Specifically, the larger the particle size r of soil, the more
The flow velocity v of the extraction solvent is increased, the flow velocity v of the extraction solvent is reduced as the bulk density ρ of the soil is increased, and the flow velocity v of the extraction solvent is reduced as the concentration c of the harmful substance in the soil is increased. First, the purification solvent supply pump 17 is controlled.

When the extraction solvent is supplied, initially, the operation valve 78 is closed and the operation valve 79 is opened, and the extraction solvent is supplied from the lower supply port 74 into the tank main body 71 to filter the filter 77.
Is immersed in the extraction solvent, then the operation valve 79 is closed and the operation valve 78 is opened, and the extraction solvent is supplied from the upper supply port 73 into the tank body 71 to immerse the soil in the extraction solvent. It is possible to more reliably suppress the flow of fine particles therein, and more reliably prevent clogging of the filtration filter 77. When the specified amount of extraction solvent is supplied to the cleaning tank 11 in this way, the control device 88 stops the operation of the refined solvent supply pump 17.

Then, the operation valve 19 is closed and the operation valve 22 is closed.
Open up. The control device 88 feedback-controls the circulation pump 23 while confirming the measurement result of the flow meter 87 so that the extraction solvent in the tank main body 71 is circulated and discharged through the circulation pipe 24 at the flow velocity v.

At this time, the turbidity meter 86 measures the turbidity (concentration of fine particles) d of the extraction solvent circulated and discharged, and the turbidity d exceeds a specified value, that is, the fine particles in the soil flow. Then, the control device 88 confirms the measurement results of the turbidity measuring device 86 and the flowmeter 87 so that the turbidity d becomes equal to or less than a specified value.
Feedback control.

That is, when the turbidity d of the extraction solvent exceeds the specified value, the circulation pump 23 is controlled so as to reduce the flow rate v of the extraction solvent.

Further, when an abnormal phenomenon such as jetting occurs on the liquid surface of the extraction solvent in the cleaning tank 11, the control device 88 suppresses the jetting or other abnormality based on the observation result of the CCD camera 85. Then, the circulation pump 23 is feedback-controlled while confirming the observation result of the CCD camera 85.

That is, when an abnormality occurs in the cleaning tank 11, the circulation pump 23 is controlled so as to reduce the flow rate v of the extraction solvent.

By circulating and discharging the extraction solvent in this manner, it is possible to extract the harmful organic substances in the soil into the extraction solvent while preventing the formation of the fine particle layer associated with the flow of the extraction solvent.

When the harmful organic substance in the soil is extracted into the extraction solvent in this way, the control device 88 stops the operation of the circulation pump 23. Then, the operation valve 22 is closed and the operation valve 19 is opened. The control device 88 confirms the measurement result of the flow meter 87 so that the extraction solvent in the tank body 71 is discharged to the discharge solvent tanks 14 and 15 through the discharge pipe 21 at the flow velocity v, and the extraction solvent discharge pump. 19 is feedback-controlled.

At this time, similarly to the above, the turbidity measuring device 86 measures the turbidity (concentration of fine particles) d of the discharged extraction solvent, and the turbidity d exceeds the specified value, that is, in the soil. When the fine particles flow, the control device 88 confirms the measurement results of the turbidity measuring device 86 and the flow meter 87 so that the turbidity d becomes equal to or less than a specified value, as described above. Meanwhile, the extraction solvent discharge pump 19 is feedback-controlled.

When all the extraction solvent has been discharged from the cleaning tank 11 in this manner, the series of operations described above is repeated several times. At this time, the concentration of the harmful organic substance in the discharged extraction solvent is measured by the concentration sensor 33, and if the measured value is equal to or lower than a predetermined value set in advance, the harmful organic substance contained in the soil of the cleaning tank 11 is detected. When the residual amount falls below the standard value specified by the official law, the work of cleaning and removing harmful organic substances from the soil is completed.

Next, by operating the blower 56 to suck the air in the cleaning tank 11, the extraction solvent remaining in the cleaning tank 11 and vaporized is taken in to dry the soil. Then, the air discharged is knocked out of the knockout pot 54.
The mist of the extraction solvent is recovered by colliding with the partition wall inside, and the gaseous extraction solvent is liquefied by cooling with the heat exchanger 55, and the gaseous extraction solvent in the air is further liquefied. Adsorb and remove with. Then, the extraction solvent recovered by the knockout pot 54 and the heat exchanger 55 is discharged by the solvent return pump 64 via the return pipe 65 to the discharged solvent tank 1
Return to 5.

After removing the harmful organic substances from the soil in the cleaning tank 11, the cleaning liquid pump 25
To supply the cleaning liquid (water) in the cleaning liquid tank 16 (water tank 16a) to each cleaning tank 11 via the supply pipe 26,
The water-soluble harmful inorganic substance (for example, potassium ferricyanide) contained in the soil is removed by washing in the same manner as the above-mentioned washing and removal of the harmful organic substance by the extraction solvent. Similarly, the alkaline liquid is circulated and discharged into and from the cleaning tank 11 for a predetermined time, and this treatment is repeated for several cycles to remove the alkali-soluble harmful inorganic substances (for example, cyanides) contained in the soil from the soil. Wash away. Further, the acidic liquid is circulated and fed into and out of the cleaning tank 11 for a predetermined time, and this treatment is performed for several cycles, thereby removing acid-soluble harmful inorganic substances (such as lead chloride) contained in the soil.

On the other hand, the extraction solvent (alcohol) in the discharge solvent tanks 14 and 15 is transferred by the transfer pump 43 to the transfer pipe 44.
To the solvent refining device 36, where the harmful organic substances are removed from the extraction solvent, and the regenerated extraction solvent is returned to the refining solvent tank 13. The harmful organic substances separated by the solvent refining device 36 are sent to an organic substance treatment device 48 through an organic substance discharge pipe 47 and are detoxified. Note that examples of the detoxification treatment method include an incineration treatment method and a hydrothermal oxidative decomposition treatment method.

In the cleaning liquid refining device 37, the harmful inorganic substances are removed from the cleaning liquid (water, alkaline liquid, acidic liquid), and the regenerated cleaning liquid is supplied to the cleaning liquid tank 16
Return to. The harmful inorganic substance separated by the cleaning liquid purification device 37 is sent to the inorganic substance processing device 53 through the inorganic substance discharge pipe 52 and is detoxified.

After that, the blower 56 is operated as necessary to suck and discharge the gas in the cleaning tank 11, whereby the cleaning tank 1
Water remaining in the soil in 1 is evaporated and dried.

After the harmful organic substances and the harmful inorganic substances are separated and removed from the soil in the washing tank 11 by the above-mentioned treatment, the soil is taken out from the washing tank 11 and returned to the natural world.

In other words, in the present embodiment, when the extraction solvent for washing the soil or the cleaning liquid such as water, alkaline liquid or acidic liquid is circulated in the soil polluted with harmful substances, the cleaning liquid is accompanied by the circulation of the cleaning liquid. The flow velocity v of the purification liquid is controlled so as to suppress the flow of fine particles in the soil.

More specifically, the flow velocity v of the cleaning liquid is preset based on the particle size r and the bulk density ρ of the soil and the concentration c of the harmful substances (especially viscous substances such as oil) in the soil. When the turbidity d of the purifying liquid exceeds a specified value, the flow velocity v of the purifying liquid is controlled so that the turbidity d becomes equal to or less than the specified value. In addition to controlling (decreasing) v, when an abnormality occurs in the cleaning tank 11, the flow velocity v of the cleaning liquid is controlled (decreasing) so as to suppress the abnormality.

By circulating and supplying the extraction solvent in this manner, it is possible to extract the harmful organic substances in the soil into the extraction solvent while preventing the formation of the fine particle layer associated with the flow of the extraction solvent.

Therefore, even when treating mud-like soil with many fine particles such as sediments of rivers, etc., a fine particle layer is generated along with the flow of the purification solvent such as the extraction solvent or the cleaning liquid. It is possible to wash and remove the harmful substances in the soil while preventing the generation of the harmful substances on the upper and lower surfaces of the soil.

Therefore, according to the present embodiment, it is possible to efficiently process the soil even if the soil contains many fine particles.

In the present embodiment, the pump 1
Although the flow rate v of the cleaning liquid is controlled by controlling 7, 20, 23, etc., instead of this, by controlling the operation valves 19, 22, 78, 79, etc. It is also possible to control the flow velocity v.

Further, in the present embodiment, the flow velocity v of the cleaning liquid is previously determined based on the particle size r and the bulk density ρ of the soil and the concentration c of the harmful substances (especially viscous substances such as oil) in the soil. Although the flow rate v of the cleaning liquid is controlled so as to reach the set value, the harmful substance concentration measuring means may be omitted depending on the type of the harmful substance (when a viscous substance such as oil is not included). It is also possible to control the flow velocity v of the cleaning liquid so that the flow velocity v of the cleaning liquid becomes a preset value based on the particle diameter r and the bulk density ρ of the soil.

Further, in this embodiment, the turbidity d of the cleaning liquid is
When the value exceeds the specified value, the flow velocity v of the cleaning liquid is controlled (decreased) so that the turbidity d becomes equal to or less than the specified value, and when an abnormality occurs in the cleaning tank 11, The flow velocity v of the cleaning liquid is controlled (decreased) so as to suppress the abnormality, but the CCD camera 8 may be used depending on the type of the harmful substance, the property of the soil, the degree of contamination, and the like.
5 or one of the turbidity measuring device 86 is omitted,
It is also possible to perform feedback control only by observing the turbidity d or the inside of the washing tank 11, and further, omitting both the CCD camera 85 and the turbidity measuring device 86 and omitting the feedback control. It is possible.

[0073]

The soil purification method according to the first invention is
When circulating the cleaning liquid for cleaning the soil in the soil polluted with harmful substances, the flow rate of the cleaning liquid is controlled so as to suppress the flow of fine particles in the soil accompanying the circulation of the cleaning liquid. Therefore, for example, even when treating soil with a large amount of fine particles such as sediment of rivers, a fine particle layer is generated on the upper and lower surfaces of the soil due to the flow of the cleaning liquid. While preventing this, the harmful substances in the soil can be efficiently washed and removed.

The soil purifying method according to the second aspect of the present invention is the soil purifying method according to the first aspect of the present invention, wherein the flow velocity of the purifying liquid has a preset value based on the particle size and bulk density of the soil. Since the flow velocity of the liquid is controlled, the effect of the first aspect of the invention can be easily and reliably obtained.

The soil purification method according to the third aspect of the present invention is the method of the first aspect, wherein the flow rate of the purification liquid is preset based on the particle size and bulk density of the soil and the concentration of the harmful substance in the soil. Since the flow rate of the purification liquid is controlled so as to reach the set value, the effect of the first invention can be easily and reliably obtained even when the harmful substance contains a viscous substance such as oil. be able to.

The soil purification method according to the fourth aspect of the present invention is the soil purification method according to any one of the first to third aspects, wherein when the turbidity of the purification liquid exceeds a specified value, the turbidity value becomes a specified value. By controlling the flow rate of the purification liquid as follows, it is possible to reliably prevent the generation of the fine particle layer along with the flow of the purification liquid from occurring on the upper surface or the lower surface of the soil, and It is possible to more reliably wash and remove the harmful substances.

According to a fifth aspect of the present invention, there is provided a method for soil purification according to any one of the first to fourth aspects, wherein the purification liquid is an organic solvent and the harmful substance is a residual organic pollutant. Since it is a harmful organic substance containing a compound or oil, the above-mentioned effects can be most exerted.

A soil purification method according to a sixth aspect of the present invention is the method according to any one of the first to fourth aspects, wherein the purification liquid is water and the harmful substance is a water-soluble harmful inorganic substance. It is possible to maximize the effect.

The soil purification method according to the seventh invention is the soil purification method according to any one of the first to fourth inventions, wherein the purification liquid is an alkaline liquid and the harmful substance is an alkali-soluble harmful inorganic substance. The above-mentioned effects can be most effectively expressed.

The soil remediation method according to an eighth aspect of the present invention is characterized in that, in any one of the first to fourth aspects of the present invention, the purification liquid is an acidic liquid and the harmful substance is an acid-soluble harmful inorganic substance. The above-mentioned effects can be most effectively expressed.

The soil purifying apparatus according to the ninth aspect of the present invention is a cleaning tank for holding soil contaminated with harmful substances, and a cleaning liquid circulating means for circulating a cleaning liquid for cleaning the soil in the soil in the cleaning tank. And, since it comprises a purification liquid flow rate control means for controlling the flow rate of the purification liquid by controlling the purification liquid flow means so as to suppress the flow of fine particles in the soil accompanying the flow of the purification liquid, For example, even when treating soil with a large amount of fine particles, such as sediment from rivers, it is possible to prevent the generation of a fine particle layer that accompanies the flow of the cleaning liquid on the upper and lower surfaces of the soil. However, the harmful substances in the soil can be efficiently washed and removed.

A soil purifying apparatus according to a tenth aspect of the present invention is the soil purifying device according to the ninth aspect, wherein the purification liquid flow rate control means measures the particle diameter of the soil, and the soil in the cleaning tank. Bulk density measuring means for measuring the bulk density, and based on the measurement results by the particle size measuring means and the bulk density measuring means, the purification liquid flow so that the flow velocity of the purification liquid becomes a preset value. Since the control means main body for controlling the means is provided, the effect of the ninth aspect of the invention can be obtained easily and reliably.

The soil purifying apparatus according to the tenth invention is
In a ninth aspect of the invention, the purification liquid flow rate control means is
Particle size measuring means for measuring the particle size of the soil, bulk density measuring means for measuring the bulk density of the soil in the washing tank, and harmful substance concentration measuring means for measuring the concentration of the harmful substance in the soil And, based on the measurement results by the particle size measuring means, the bulk density measuring means and the harmful substance concentration measuring means,
Since the control means main body that controls the purification liquid flow means is provided so that the flow velocity of the purification liquid becomes a preset value, the effect according to the first aspect of the invention can be easily and reliably obtained. .

The soil purifying device according to the twelfth invention is
In any one of the ninth to tenth inventions, the purified liquid flow rate control means includes a turbidity measurement means for measuring the turbidity of the purified liquid, and the control means body is the turbidity measurement means. When the turbidity exceeds a specified value based on the measurement result in, the purification liquid flow means is controlled so that the turbidity is equal to or less than the specified value. It is possible to reliably prevent the formation of a layer from occurring on the upper surface or the lower surface of the soil, and it is possible to more reliably wash and remove the harmful substances in the soil efficiently.

The soil purifying apparatus according to the thirteenth invention is
In any one of the ninth to twelfth inventions, the purified liquid flow rate control means includes a cleaning tank inside observation means for observing a state inside the cleaning tank, and the control means main body is inside the cleaning tank. Based on the observation result by the observation means, when an abnormality occurs in the cleaning tank, the purification liquid flow means is controlled so as to suppress the abnormality. Even if the layer is formed on the upper surface or the lower surface of the soil, the harmful substance in the soil can be reliably washed and removed.

[Brief description of drawings]

FIG. 1 is a schematic configuration diagram of an embodiment of a soil purifying apparatus according to the present invention.

FIG. 2 is an explanatory diagram of a soil cleaning method.

FIG. 3 is a schematic structural diagram of the cleaning tank of FIG.

[Explanation of symbols]

11 washing tank 12 tank units 35 Purification unit 36 Solvent Purifier 37 Cleaning solution purifier 38 Dryer 66 Grow-out device 71 tank body 72 Lid 76 Support 77 Filtration filter 81 Particle size measuring instrument 82 Hazardous substance concentration measuring instrument 83 Weighing machine 84 Stacking height measuring instrument 85 CCD camera 86 Turbidity meter 87 Flowmeter 88 Control device 89 monitor

   ─────────────────────────────────────────────────── ─── Continued front page    (72) Inventor Hideo Suzuki             1-1 1-1 Wadasaki-cho, Hyogo-ku, Kobe-shi, Hyogo             No. Mitsubishi Heavy Industries, Ltd.Kobe Shipyard (72) Inventor Naoyuki Uejima             2-1-1 Niihama, Arai-cho, Takasago City, Hyogo Prefecture             Takasago Laboratory, Mitsubishi Heavy Industries, Ltd. (72) Inventor Akihiro Hamasaki             2-1-1 Niihama, Arai-cho, Takasago City, Hyogo Prefecture             Takasago Laboratory, Mitsubishi Heavy Industries, Ltd. (72) Inventor Taku Arikawa             2-1-1 Niihama, Arai-cho, Takasago City, Hyogo Prefecture             Takasago Laboratory, Mitsubishi Heavy Industries, Ltd. F-term (reference) 4D004 AA41 AB02 AB03 AB06 AB07                       CA40 CC03 CC04 CC12 DA01                       DA02 DA10 DA12 DA20

Claims (13)

[Claims] 1. When the cleaning liquid for cleaning the soil is circulated through the soil polluted with harmful substances, the flow velocity of the cleaning liquid is controlled so as to suppress the flow of fine particles in the soil due to the circulation of the cleaning liquid. The soil purification method is characterized in that the soil is controlled. 2. The flow rate of the cleaning solution according to claim 1, wherein the flow rate of the cleaning solution is controlled based on the particle size and the bulk density of the soil so that the flow rate of the cleaning solution becomes a preset value. Soil purification method. 3. The purification liquid according to claim 1, wherein the flow velocity of the purification liquid has a preset value based on the particle size and bulk density of the soil and the concentration of the harmful substance in the soil. A soil purification method characterized by controlling the flow velocity of the soil. 4. In any one of claims 1 to 3, when the turbidity of the cleaning liquid exceeds a specified value, the flow rate of the cleaning liquid is adjusted so that the turbidity becomes equal to or less than the specified value. A soil purification method characterized by controlling. 5. The cleaning liquid according to claim 1, wherein the cleaning liquid is an organic solvent, and the harmful substance is a harmful organic substance containing a halogen compound or oil which is a residual organic pollutant. A soil purification method characterized by being present. 6. The soil purification method according to claim 1, wherein the cleaning liquid is water, and the harmful substance is a water-soluble harmful inorganic substance. 7. The soil purification method according to claim 1, wherein the cleaning liquid is an alkaline liquid, and the harmful substance is an alkali-soluble harmful inorganic substance. 8. The soil cleaning method according to claim 1, wherein the cleaning liquid is an acidic liquid, and the harmful substance is an acid-soluble harmful inorganic substance. 9. A cleaning tank for holding soil polluted with harmful substances, a cleaning liquid circulating means for circulating a cleaning liquid for cleaning the soil in the soil in the cleaning tank, and a circulation liquid for the cleaning liquid. A soil purification device comprising: a purification liquid flow rate control unit that controls the purification liquid flow unit so as to suppress the flow of fine particles in the soil and controls the flow velocity of the purification liquid. 10. The particle size measuring unit for measuring the particle size of the soil, and the bulk density measuring unit for measuring the bulk density of the soil in the cleaning tank according to claim 9. A control means main body that controls the purification liquid flow means so that the flow velocity of the purification liquid becomes a preset value based on the measurement results of the particle size measurement means and the bulk density measurement means. Soil purification device characterized by being 11. The particle size measuring means for measuring the particle size of the soil, and the bulk density measuring means for measuring the bulk density of the soil in the cleaning tank according to claim 9. , A harmful substance concentration measuring means for measuring the concentration of the harmful substance in the soil, based on the measurement results by the particle size measuring means, the bulk density measuring means and the harmful substance concentration measuring means, A soil purifying device, comprising: a control means main body that controls the purification liquid circulating means so that the flow velocity has a preset value. 12. The purifying liquid flow rate control means according to claim 9, further comprising turbidity measuring means for measuring the turbidity of the purifying liquid, and the control means main body includes the turbidity. Based on the measurement result by the measuring means, when the turbidity exceeds a specified value, the soil purification apparatus is controlled so that the turbidity becomes equal to or less than the specified value. . 13. The cleaning liquid flow rate control means according to claim 9, wherein the cleaning liquid flow rate control means includes a cleaning tank inside observation means for observing a state inside the cleaning tank, and the control means main body includes the cleaning means. Based on the result of observation by the in-tank observation means, if an abnormality occurs in the cleaning tank,
A soil purifying device, characterized in that the purification liquid circulating means is controlled so as to suppress the abnormality.