JP3508997B2 - How to clean contaminated soil - Google Patents

Description

Description: BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method for cleaning contaminated soil contaminated with volatile organic compounds, heavy metals, oils, etc. The present invention relates to a method for cleaning contaminated soil that can purify contaminated soil in situ without purifying the contaminated soil in a soil cleaning plant or the like. [0002] Conventionally, volatile organic compounds, heavy metals,
As a method for cleaning soil contaminated with oil or the like, a soil cleaning plant method for transporting excavated contaminated soil to a soil cleaning plant for cleaning, and a soil flushing method for cleaning contaminated soil in situ without excavating contaminated soil are known. ing.
In any of these cleaning methods, oil and other contaminants existing in the gaps of the soil or adhering to the soil are separated into a liquid phase and removed. [0003] In brief, the above-mentioned soil cleaning plant method is described. First, the excavated contaminated soil is transported to a soil cleaning plant to remove coarse substances from the contaminated soil. Then, the contaminated soil is sieved through a primary sieve, the portion passed through the sieve is sent to a wet sieve, and the soil mass to which contaminants are attached is broken by high-pressure washing. The contaminated soil slurried by the wet sieve is sent to a cyclone or the like and classified. The classified fine-grained contaminated soil is subjected to dehydration treatment or the like, and then detoxified or disposed of. The coarse-grained contaminated soil is further purified by a washing operation. In this way, the coarse fraction of the purified soil is buried in the excavated place or buried in another place, and the treatment of the contaminated soil is completed. [0004] In this soil cleaning plant method, as described above, an operation of excavating contaminated soil, an operation of transporting the excavated contaminated soil to a cleaning plant, and an operation of cleaning the transported contaminated soil with a purification device in the plant are indispensable. It is.
In addition, it is necessary to backfill the ground after excavating the washed soil or the alternative soil, and the transportation for backfilling and the civil work for backfilling are added to the work. As described above, the soil cleaning plant method requires a large amount of civil engineering equipment and purification equipment, and is a very expensive cleaning method requiring many man-hours. Next, a description will be given of a soil flushing method for cleaning contaminated soil in situ without excavating it. This soil flushing method is described in FIGS.
Are generally known, and each method will be described with reference to the drawings. In the soil flushing method shown in FIG. 4, water or a cleaning liquid (hereinafter referred to as a cleaning liquid) is sprayed on the ground of the contaminated soil b with a sprinkler a or a penetration groove (not shown). The cleaning liquid sprayed on the ground penetrates into the ground, and the cleaning liquid that has permeated the contaminated soil becomes a cleaning liquid containing contaminants, flows into groundwater, and flows over the impermeable layer c. Groundwater containing the pollutant (washing liquid)
Is sucked from the well d by the pump e, collected, and sent to a water treatment plant (not shown). Then, in the water treatment plant, for example, heavy metals contained in groundwater (washing liquid) are removed by lime precipitation and organic substances are removed by means such as activated carbon adsorption and aeration. The groundwater (cleaning liquid) thus purified is fed to the sprinkler a by the pump f and used repeatedly for soil cleaning. In the soil flushing method shown in FIG. 5, wells h and i are installed on both sides of the contaminated soil b.
The cleaning liquid is injected from the cleaning liquid container j into one well h.
And the said washing | cleaning liquid contains a pollutant by passing through the contaminated soil b. The cleaning liquid containing the contaminants is forcibly pumped from the well i on the opposite side and supplied to the separator k. The cleaning liquid containing the contaminant supplied to the separator k is separated into the cleaning liquid and the contaminant. Then, the separated cleaning liquid is again supplied to the cleaning liquid container j and reused. On the other hand, the separated contaminants are applied to the processing machine m to be separated into water n, gas and concentrate p, and the water is reused for washing water and the like. Also,
The gas is processed by a gas processor q and the concentrate p is subsequently processed or discarded. As described above, in any of the soil flushing methods, the cleaning liquid is injected into the contaminated soil to extract the contaminants gradually. Therefore, unlike the soil cleaning plant method, it is not necessary to excavate the contaminated soil, and the soil can be cleaned in situ (in situ). In addition, there is an advantageous aspect that no man-hour is required. [0008] Incidentally, as described above, the soil flushing method has various advantages as compared with the soil cleaning plant method, but it still has the following technical problems. Challenges remain. (1) In any of the soil flushing methods shown in FIGS. 4 and 5, it is necessary to install a well for pumping groundwater and a pump for pumping groundwater from the well.
There was a problem that the pump had to be operated for a long time in order to remove pollutants from the contaminated soil. (2) The cleaning efficiency of contaminated soil is related to the size of soil particles. That is, in general, contaminants are easily removed from coarse particles of soil particles, but difficult to remove from fine particles. Therefore, there is a problem that the contaminants attached to the fine-grained soil cannot be sufficiently washed. (3) In the soil flushing method, groundwater is pumped up by the negative pressure of the suction well, so that there is a region where the gap between the soil particles is not filled with the washing liquid, that is, an unsaturated zone. In this unsaturated zone, the contact between the cleaning liquid and the soil particles does not occur, and the desorption and desorption of contaminants adsorbed on the particle surface is prevented.
There was a problem that some parts were not removed. (4) In addition, there is a phenomenon that the flow of water in the unsaturated zone locally passes only through a portion where the porosity of the soil particles is large, that is, a so-called water path, and the flow of the cleaning liquid is limited to the water path. Therefore, there was a problem in that the entire stratum was efficiently purified. (5) When a clay layer having poor water permeability partially exists in the area of the contaminated soil, the entire flow of the cleaning liquid is hindered by the clay layer, and the recovery / circulation speed of the cleaning liquid is reduced. There was a problem that it was sometimes too small. (6) If groundwater (cleaning liquid) containing contaminants diffuses around contaminated soil, unpolluted soil will be contaminated, and the contaminated area will be expanded, causing a problem of so-called secondary pollution. was there. SUMMARY OF THE INVENTION The present invention has been made to solve such a technical problem, and does not require installation of a well or a pump for pumping up, and does not cause a problem of secondary pollution which enlarges a pollution area. It is an object of the present invention to provide a method for cleaning contaminated soil that can uniformly and sufficiently purify the entire contaminated soil even if fine-grained soil is present in part of the contaminated soil. In particular, in the method of the present invention, since the groundwater is entirely raised and an upward groundwater flow is generated in the area of the contaminated soil, the unsaturated zone described in the above (3) and (4) is not formed. The entire contaminated soil area can be saturated with the cleaning liquid (saturated zone), and thus all of the soil particle gaps are filled with the cleaning liquid, so that the entire area can be sufficiently and efficiently cleaned. [0012] The method for cleaning contaminated soil according to the present invention, which has been made to achieve the above object, comprises the steps of:
Providing an outer boundary wall for blocking the contaminated soil, providing an inner partition wall in the outer boundary wall for dividing a region surrounded by the outer boundary wall so that a lower end thereof reaches the lowermost part of the contaminated soil; Supplying a cleaning liquid to one of the divided areas, forming a flow of the cleaning liquid from one area to the other area, and collecting a cleaning liquid containing a pollutant discharged to the ground surface of the other area; It is characterized by. In the method for cleaning contaminated soil according to the present invention configured as described above, since the lower end of the outer boundary wall has a depth reaching the impermeable layer in the ground, the area contaminated with the cleaning liquid containing the contaminant is contaminated. There is no more spread. Further, the lower end of the inner partition wall has a depth reaching the lowest part of the contaminated soil, but does not reach the impermeable layer in the ground, so one of the regions formed by the outer boundary wall and the inner partition wall. And the other region communicate below the lower end of the inner partition wall. Therefore, the cleaning liquid supplied to one area flows from the soil in one area and moves to the other area, purifying the contaminated soil during the transfer process, and the cleaning liquid contains a cleaning liquid containing contaminants. It becomes. The cleaning liquid containing the contaminants is drained to the ground surface in the other area. The drained cleaning liquid is collected and processed. Here, the outer boundary wall is a water-impervious wall formed on the outer periphery of the contaminated soil so that its lower end reaches the impermeable layer and its upper end is higher than the ground surface. The inner partition wall that divides the area surrounded by the outer boundary wall is a water impermeable wall formed so that the lower end thereof reaches the lowermost part of the contaminated soil and the upper end thereof is higher than the ground surface. The cleaning liquid is supplied to one of the areas, and the liquid level of the cleaning liquid is kept higher than the ground surface by the outer boundary wall and the inner partition wall or by the inner partition wall. It is desirable to form the flow of the cleaning liquid from the other region to the other region, and to collect the cleaning liquid containing contaminants discharged to the ground surface in the other region. In the cleaning method for contaminated soil according to the present invention, the liquid level of the cleaning liquid is kept higher than the ground surface by the outer boundary wall and the inner partition wall or by the inner partition wall. Accordingly, the flow of the cleaning liquid from one region to the other region can be formed by the head pressure of the cleaning liquid. Therefore, the cleaning liquid supplied to one area flows in from the soil in one area by the head pressure and moves to the other area, purifying the contaminated soil in the movement process, and the cleaning liquid contains the cleaning liquid containing the contaminant. It becomes. The cleaning liquid containing the contaminant is drained to the ground surface in the other area by the head pressure. The drained cleaning liquid is collected and processed. By keeping the level of the cleaning liquid on the ground surface of the other area constant, the head pressure is maintained, so that the cleaning of the contaminated soil continues continuously and the contaminated soil is purified. At this time, a steel sheet pile, a stirring / mixing type impermeable wall, concrete or the like is used as the impermeable wall, but a steel sheet pile or a stirring / mixing type impermeable wall is preferable. When the impermeable wall is a steel sheet pile or an agitation mixed type impermeable wall, the impermeable wall, that is, the outer boundary wall and the inner partition wall can be easily provided. As a method of installing the impermeable wall, an ordinary method such as a method by casting is sufficient. It is desirable that a sand pile be provided in a region surrounded by the outer boundary wall. Since the sand pile provided in this manner is extremely excellent in water permeability (water permeability), the cleaning liquid easily flows (permeates) into one area,
Further, the permeated cleaning liquid is easily drained from the ground surface in the other area, and the recovery / circulation speed of the cleaning liquid can be increased. In particular, even if there is a poorly permeable layer such as a clay layer that partially blocks water flow in the contaminated soil, the flow of the cleaning liquid can be secured through this sand pile, and the recovery / circulation speed of the cleaning liquid can be reduced. Can be faster. It is preferable that a drainage layer of geotextile is laid on the ground surface of the other area to collect a cleaning liquid containing pollutants drained on the ground surface. Geotextiles are woven fabrics, nonwoven fabrics and knitted fabrics used for strengthening and protecting earth structures.
It means a sheet-like polymer material having water permeability. It is preferable that the cleaning liquid containing the contaminants collected by the geotextile is collected in a water collecting groove and drained from the water collecting groove to a drain pipe communicating with the outside of the outer boundary wall. . With this configuration,
The cleaning solution containing the contaminants collected by the geotextile can be collected in a drain and drained out of the outer boundary wall through a drain. Further, the cleaning liquid is water, a surfactant,
Desirably, it is an acid, alkali, hot water or the like. Contaminants can be efficiently removed by using water, a surfactant, an acid, an alkali, warm water, or the like as the cleaning liquid, while the area to which the cleaning liquid is applied is surrounded by an outer boundary wall and an impermeable layer. Therefore, so-called secondary contamination due to the cleaning liquid does not occur. FIG. 1 shows an embodiment of the present invention.
This will be described with reference to FIG. FIG. 1 is a longitudinal sectional view of a cleaning facility used in the method for cleaning contaminated soil according to the present invention, FIG. 2 is a plan view of FIG. 1, and FIG. 3 is a sectional view taken along line XX of FIG. In the figure, reference numeral 1 denotes an outer boundary wall, and the outer boundary wall 1 is formed by placing a water impervious wall such as a steel sheet pile around the outside including the contaminated soil A. As shown in FIG. 2, the outer boundary wall 1 is formed by combining side ends of steel sheet piles or the like with each other and forming a rectangular peripheral wall surrounding the outside of the contaminated soil A. As shown in FIG. 1, the lower end of the impermeable wall, such as a steel sheet pile, constituting the outer boundary wall 1 is driven to a depth reaching the water-impermeable layer B, and the cleaning liquid C permeated into the ground. It does not leak outside (periphery) of the outer boundary wall 1. On the other hand, the upper end of the impermeable wall such as a steel sheet pile forming the outer boundary wall 1 is formed higher than the ground surface to store the cleaning liquid C inside the outer boundary wall 1 as described later. As the cleaning liquid C used in the present method, an appropriate one for each substance to be removed, such as water, a surfactant, an acid, an alkali, and warm water, is selected. The water, the surfactant, the acid, the alkali, and the hot water are preferable because the contaminants can be efficiently removed. Surfactants are adsorbed on the interface between water and oil and reduce the surface tension, thereby reducing the viscosity of the oil and increasing its solubility in water.As a result, the oil particles are desorbed from the soil particles, This has the effect of increasing the mobility of oil particles in the soil particle gap. In the case of warm water, an effect of increasing the solubility of contaminants in water and an effect of dissolving the organic substances themselves when the contaminants adhere to the organic substances on the surface of the soil particles can be expected.
Similarly, in the case of an acid or an alkali, an effect of increasing the solubility of a pollutant in water or promoting the dissolution of organic substances on the surface of soil particles to which the pollutant adheres can be expected. Further, inside the outer boundary wall 1, an inner partition wall 2 for partitioning an area inside the outer boundary wall 1 is provided. This inner partition wall 2 is formed by casting a water impervious wall such as a steel sheet pile. The inner partition wall 2 may have any shape as long as it divides the area inside the outer boundary wall 1, but FIG. 2 shows a case where the inner partition wall 2 is a rectangular peripheral wall and is divided into two. The inner partition 2 constituting the inner partition 2
As shown in FIG. 1, the lower end is driven to a depth that reaches the bottom of the contaminated soil A but does not reach the impermeable layer B, and is divided into two by the inner partition wall 2. The region communicates below the lower end of the inner partition wall 2. Therefore, if the cleaning liquid C is pressurized and penetrated from the ground surface of one of the two divided regions, it passes below the lower end of the inner partition wall 2 and is drained to the ground surface of the other region. You. Further, the upper end of the inner partition wall 2 is cast at substantially the same height as the upper end of the outer boundary wall 1, and a region sandwiched between the outer boundary wall 1 and the inner partition wall 2 is provided with a cleaning liquid for storing the cleaning liquid C. It is formed as a road 3. The washing liquid passage 3 can store the washing liquid C at a predetermined level from the ground surface, and the area (soil) where the washing liquid C is sandwiched between the outer boundary wall 1 and the inner partition wall 2 by the head pressure of the washing liquid C. From the ground surface to the ground. Then, the flow of the cleaning liquid C from the region (the cleaning liquid passage 3) sandwiched between the outer boundary wall 1 and the inner partition wall 2 toward the region 4 surrounded by the inner partition wall can be formed. As shown in FIG. 1, the outer boundary wall 1 and the inner partition wall 2 are provided with a cleaning liquid passage for preventing a water impervious wall such as a steel sheet pile from inclining and preventing the cleaning liquid C from leaking. 3
The embankment 5 of the cohesive soil is provided from the outside. Further, the flow of the cleaning liquid C from the region (the cleaning liquid passage 3) sandwiched between the outer boundary wall 1 and the inner partition wall 2 toward the region 4 surrounded by the inner partition wall 2 is further improved. Therefore, the sand pile 6 by the packed drain method is provided in the area (the cleaning liquid passage 3) sandwiched between the outer boundary wall 1 and the inner partition wall 2 and the area 4 surrounded by the inner partition wall.
Are installed at substantially equal intervals (FIG. 2 shows only the sand pile 6 in a partial area). In this pack drain method, a water-permeable bag is suspended in a casing pipe having a lid that can be opened and closed at the lower end, and while the bag is filled with highly water-permeable sandy soil, the casing pipe is removed. This is a method of forming a sand permeable pile 6 with high water permeability in the ground by pulling out a casing pipe after being driven into the ground, and is a conventionally generally known method, and therefore, detailed description is omitted. I do. Since the sand pile 6 thus formed has excellent water permeability, the cleaning liquid C can be led out to the ground surface and drained. In particular, even if there is a clay layer that partially impedes water flow (permeability) in the contaminated soil, the flow of the cleaning liquid can be ensured through the sand pile 6 and the recovery / circulation speed of the cleaning liquid can be increased. Can be. A geotextile drainage layer 7 is laid on the ground surface of the region 4 surrounded by the inner partition wall 2 to collect the cleaning liquid C containing the contaminants drained on the ground surface of the region 4. It is configured to be able to. Further, a water collecting groove 8 is provided in the area 4 surrounded by the inner partition wall 2, and the cleaning liquid C containing the contaminant collected by the geotextile drainage layer 7 is supplied to the water collecting groove 8.
It is structured so that it can be collected. Further, the cleaning liquid C is configured to be sent to the water treatment facility 10 from the water collecting groove 8 through a drain pipe 9 penetrating the outer boundary wall 1. The contaminants are separated from the cleaning liquid C sent to the water treatment facility 10, and the cleaning liquid C is discharged to sewage or recycled as the cleaning liquid C again. Further, by way specifically an example of the size of the inner partition walls 2 and the liquid water channel 3, as shown in FIG. 2, when one side L ₁ of the inner partition wall 2 is 30 to 50 m, the liquid water channel 3 width L ₂ of the is set to 3 to 5 m. The steps of the method for cleaning contaminated soil according to the present invention will be described. First, the cleaning liquid C is stored in the cleaning liquid path 3. By maintaining the level of the cleaning liquid C at a constant level, the cleaning liquid C permeates into the soil from the cleaning liquid passage 3 due to the head pressure. The cleaning liquid C takes in contaminants while passing through the contaminated soil A, passes below the inner partition wall 2, and moves to a region 4 surrounded by the inner partition wall 2. In FIG. 1, the movement of the cleaning liquid C is indicated by arrows. In particular, since the cleaning liquid C flowing into the sand pile 6 from the cleaning liquid passage 3 flows out from the entire surface of the sand pile 6 to the surrounding soil (see the arrow in FIG. 1), more cleaning liquid C can be permeated. it can. As a result, the flow of the cleaning liquid C becomes smooth, and while the contaminated soil A below the cleaning liquid passage 3 is entirely cleaned, the cleaning liquid C passes below the inner partition wall 2 into the area 4 surrounded by the inner partition wall. Inflow. The cleaning liquid C flowing into the area 4 surrounded by the inner partition wall passes through the sand pile 6 in the area 4 (partially) while further cleaning the contaminated soil A in the area 4. The cleaning liquid C is directly passed without passing through the sand pile 6),
Drained to the ground surface. At this time, the pore water existing in the soil is also drained together with the cleaning liquid C. Further, the cleaning liquid C containing the contaminants drained to the ground surface of the region 4 is collected by the laid geotextile drainage layer 7. Further, the cleaning liquid C collected by the drainage layer 7 of the geotextile is collected in a water collecting groove 8 and is drained by a drain pipe 9.
Is discharged to the water treatment device 10 on the outer boundary wall through which the water is discharged, and a predetermined process is performed. As described above, the cleaning solution C containing the contaminants is used.
Is constantly drained from the ground surface of the area 4 surrounded by the inner partition wall 2, so that the polluted soil A is gradually purified with time. Also, the outer boundary wall 1 and the inner partition wall 2
From the area (washing liquid passage 3) sandwiched between
The flow of the cleaning liquid C toward the region 4 surrounded by the cleaning liquid C is formed, in other words, the flow of the cleaning liquid C directed inward with respect to the outer boundary wall 1 is formed. Diffusion can be further prevented, and contaminated soil can be efficiently washed. Although the flow of the cleaning liquid C as described above is generated only by the head pressure of the cleaning liquid C on the cleaning liquid passage 3, even if there is fine-grained soil (clay soil) having poor water permeability, the Since the pile 6 promotes the flow of the cleaning liquid C, the soil is smoothly cleaned. Further, since the sand piles 6 are arranged at equal intervals, it is possible to form a flow that circulates the entire soil in the outer boundary wall 1 almost evenly. When comparing the equipment used for the method for cleaning contaminated soil according to the present invention with the conventional equipment for cleaning contaminated soil, the equipment used for soil cleaning according to the present invention shows that the impermeable walls such as steel sheet piles are used. An outer boundary wall 1 and an inner partition wall 2 are provided, and a pumping well as in the conventional equipment is not required, and a well water pump is not required. In the conventional example, a large construction machine such as an excavating machine for digging a well is required. However, according to the present invention, since only a driving facility such as a steel sheet pile is required, the installation is easy and the installation cost is low. Further, in the conventional example, the well water pump must be continuously operated for a long time to wash the soil. On the other hand, in the present invention, only the washing liquid C is maintained at a predetermined liquid level, and the washing is carried out. It can be performed. Further, in the conventional example, it is not possible to prevent the secondary pollution in which the groundwater diffuses the contaminant to the surroundings, but in the present invention, the secondary boundary wall 1 can surely prevent the secondary pollution. In the conventional example, in an area away from the well water pump,
Although the flow of the cleaning liquid C is poor and the contaminated soil is not easily cleaned, in the present invention, since the cleaning liquid C is infiltrated, the cleaning liquid C flows uniformly throughout the soil, and uneven cleaning does not occur. In the above-described embodiment, the outer boundary wall 1 and the inner partition wall 2 are formed by placing a steel sheet pile or a stirring and mixing type impermeable wall. The present invention is not limited to the mixed type impermeable wall. For example, the outer boundary wall and the inner partition wall may be formed by excavation and a continuous continuous underground wall. However, in this case, the construction cost is higher than steel sheet piles or the stirring and mixing type impermeable wall, but it is cheaper than the conventional case where contaminated soil is removed by an excavator. The method for cleaning contaminated soil according to the present invention comprises:
With such a configuration, power costs and the like consumed during a long cleaning period can be reduced without installing a well or a pump for pumping up, and it is economical. In addition, even if the contaminated soil is fine-grained soil, the entire contaminated soil can be uniformly and sufficiently washed without causing the problem of secondary contamination in which the contaminated area is enlarged.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a longitudinal sectional view of a cleaning facility used in the method for cleaning contaminated soil according to the present invention. FIG. 2 is a plan view of FIG. FIG. 3 is a sectional view taken along line XX of FIG. 2; FIG. 4 is an explanatory diagram of a conventional soil flushing method. FIG. 5 is an explanatory diagram of another conventional soil flushing method. [Description of Signs] A Contaminated soil B Impermeable layer C Washing liquid 1 Outer boundary wall 2 Inner partition wall 3 Washing liquid passage (area sandwiched between outer boundary wall and inner partition wall) 4 Enclosed by inner partition wall Area 5 Embankment 6 Sand pile 7 Geotextile drainage layer 8 Ditch 9 Drainage pipe 10 Water treatment device

────────────────────────────────────────────────── ─── Continuation of front page (72) Inventor Keisuke Matsukawa 2-1-1, Tsurumichuo, Tsurumi-ku, Yokohama-shi, Kanagawa Prefecture (56) References JP-A-7-42130 (JP, A) JP-A-7-136631 (JP, A) JP-A-10-258266 (JP, A) JP-B-46-7348 (JP, B1) JP-B-40-18586 (JP, B1) US Patent 5054961 (US, A) (58) Search Field (Int.Cl. ⁷ , DB name) B09C 1 / 02,1 / 08 E02D 3/12

Claims (1)

(57) [Claims 1] Contaminated soil is wrapped around the outside of the contaminated soil so that its lower end reaches an impermeable layer and its upper end is higher than the ground surface . Providing an outer boundary wall to be closed, in the outer boundary wall, such that the lower end thereof reaches the lowest part of the contaminated soil and the upper end thereof is higher than the ground surface ,
Wherein the inner partition wall provided for dividing the area surrounded by the outer boundary wall, by supplying a cleaning liquid to the divided one regions, the washing
The liquid level of the purified liquid is determined by the outer boundary wall and the inner partition wall.
Or the inner partition wall holds the cleaning liquid higher than the ground surface , forms a flow of the cleaning liquid from one area toward the other area by the head pressure of the cleaning liquid, and removes pollutants discharged to the ground surface in the other area. A method for cleaning contaminated soil, comprising recovering a contained cleaning solution.