KR20080101145A - Shielding layer and method of multilayer soil addition restoring using the same - Google Patents

Abstract

A polluted soil barrier layer is provided to reduce the concentration of pollutant about dilute and to prevent the suppression, the neutralization, and the second prevention of environmental contamination by an additive. A polluted soil barrier layer comprises a heavy metal rising barrier layer(21) for blocking the heavy metal and the hydrogen ion rising from the pollute soil(10) of the lower part the neutralization, a moisture rising barrier layer(22) which is formed with the material in which the air gap is large and lowers the capillary tube high, an earth and sand barrier layer(23) consisting of the ecologically friend material in order to be disassembled after inflow of earth and sand intercepting part for two or three years.

Description

Contaminated soil barrier layer and functional multi-layer soil restoration method using the same {SHIELDING LAYER AND METHOD OF MULTILAYER SOIL ADDITION RESTORING USING THE SAME}

1 is a structural diagram showing a contaminated soil blocking layer according to the present invention.

2 is a first schematic diagram of a functional multi-layer soil restoration method according to the present invention.

3 is a second schematic diagram of a functional multi-layer soil restoration method according to the present invention.

Figure 4 is a third schematic diagram of the functional multi-layer soil restoration method according to the present invention.

5 is a flow chart of a functional multi-story soil restoration method according to the present invention.

<Indication of symbols for main parts of drawing>

10, 10 ': Soil 11: Soil Contaminated

20: contaminated soil barrier layer 21: neutralization and heavy metal rising barrier layer

22: moisture rise blocking layer 23: soil inflow blocking layer

30, 30 ': non-contaminated soil

S100: Contamination Site Inspection Step

S110: Steps to determine whether pollution exceeds environmental standards / plant transition

S120: Depth of High Contamination

S130: Whether the target can be achieved by improving the topsoil

S140: first functional multi-story soil stage

S150: Functional Floor Improvement Phase of Contaminated Soil

S160: ground level problem due to cover

S170: second functional multi-story soil stage

S180: third functional multi-story soil stage

S190: Derivation and application of fertilization criteria in consideration of plant growth and heavy metal behavior

S200: Completion and monitoring stage of the contaminated site restoration construction using the guest soil restoration method

The present invention relates to a contaminated soil barrier layer and a functional soil recovery method using the same, and more specifically, to solve the deterioration of pollution by leaching and fertilizing arsenic and hexavalent chromium, which are problems of the existing soil recovery method, Improve soil contamination by using high quality soils and additives to secure concentrations below environmental standards, prevent plant transition, maintain proper growth of plants, and ensure proper pH, or place contaminated soil underneath and block neutralization and increase of heavy metals. A contaminated soil barrier layer consisting of a layer, a moisture rise barrier layer, and a soil inflow barrier layer is installed at a stop, and a non-contaminated soil is formed at the top to securely isolate the contaminated soil, thereby increasing the contaminants and moisture caused by the capillary phenomenon. By blocking, soil layer (fill layer) to secure the durability of restoration efficiency and promote plant growth It relates to soil contaminated barrier layer, and a functional gaekto restoration method using the same for preventing the salt.

In general, soils contain some heavy metals, either naturally occurring or through artificial routes. Many heavy metals, including lead, copper, cadmium, zinc and mercury, are essential for a variety of organisms, such as plants that receive a lot of nutrients from the soil if they are maintained in the soil, In some cases, direct and indirect routes have very harmful effects on humans. As industrialization progresses rapidly, various harmful substances are dumped and spilled, which seriously pollutes soil and groundwater. In particular, in industrial areas, urban waste treatment areas, and abandoned mines and coal mines, the concentration of heavy metals in the soil is reported to be several hundred times higher than that of natural soils in the general area. Soil pollution caused by high industrialization is emerging as a major hazard to human beings beyond the natural capacity of soil, so polluted soil to remove heavy metals contained in soil Is not only a matter of proper coordination of ecosystems, but also a problem of human survival.

Heavy metals spilled due to accident or unauthorized dumping react with soil through various paths, and the rate of reaction varies depending on the amount and nature of organic matter, clay and hydroxide in the soil. Conventionally, various studies have been made to remove heavy metals present in the soil, and among them, ion exchange resins or electrolysis have been the mainstream. However, these methods do not have useful aspects for the treatment and recovery of heavy metals with high purity, but they are not very effective for general soil purification methods in which the purity of heavy metals is slightly reduced or other contaminants are contained in addition to heavy metals. It was flawed. In addition, the problem that the economic feasibility of investing in the facility in purifying heavy metal contaminated soils over large areas also remained a challenge to be solved. Among them, soil washing has been the mainstream. However, the soil washing method has no useful aspects in restoring heavy metal contaminated soils, but it has a drawback that it is not effective as a method for purifying soils containing other pollutants in addition to heavy metals. In addition, the problem of lack of economic feasibility in purifying heavy metal contaminated soils over large areas remains a challenge.

For this reason, the work of transporting contaminated soil to an appropriate place for disposal and filling it with new safe soil has been developed and implemented. In detail, the method of restoring the contaminated soil,

Current methods in Korea are polluted topsoil removal and pure soil application method, which removes 50cm of topsoil and fills the upper part with high quality soil. However, this has a disadvantage in that a high probability of contamination of the pure soil layer due to the increase of heavy metals and hydrogen ions due to the capillary phenomenon.

In addition, if you look at the current method of Japan, the method of reversing the contaminated soil and the non-contaminated soil, the separation of the contaminated soil and the non-contaminated soil, and reverse the position of the contaminated soil by the capillary phenomenon also rises As a result, the upper non-contaminated soil has a high probability of being contaminated.

Therefore, there is an urgent need to develop a functional multi-layer soil that can prevent the rise of pollutants from underlying soil by blocking the rise of pollutants.

The present invention has been made to solve the above problems, an object of the present invention is to reduce the pollution concentration for dilution using a functional soil material consisting of high quality soil and additives, plant transition of heavy metals by additives It aims to provide restoration of soil that improves the topsoil which can be suppressed, neutralized and prevented secondary environmental pollution.

Contain the contaminated soil in the order from the lower part to the contaminated soil, the contaminated soil barrier layer, and the non-contaminated soil layer in order to effectively block the hydrogen ions, heavy metals, and water that are raised by the capillary effect. It is to provide a functional multi-layer soil restoration method using a contaminated soil barrier layer that enables the stabilization of heavy metals in the restored topsoil, prevention of plant transfer and growth.

Other objects and advantages of the invention will be described below and will be appreciated by the embodiments of the invention. Furthermore, the objects and advantages of the present invention can be realized by means and combinations indicated in the claims.

The present invention has the following features to achieve the above object.

According to an embodiment of the present invention, a non-contaminated soil is deposited on top of a contaminated soil to safely isolate a contaminated soil, and is located between the contaminated soil and a non-contaminated soil, and the hydrogen rises from the contaminated soil to a non-contaminated soil. Neutralization for effectively blocking hydrogen ions and heavy metals located above the non-polluted soil and effectively rising from the polluted soil under the capillary phenomenon or groundwater level in order to effectively block the increase of pollutants and moisture such as ions and heavy metals. And a heavy metal rising barrier layer; Located on top of the neutralization and heavy metal rising barrier layer, the moisture rise blocking layer is formed of a large pore material to block water and contaminants rising from the soil contaminated by capillary action to lower the capillary height; The water-permeable membrane is positioned above the moisture-rise blocking layer, and the soil is introduced into the air gap formed by the moisture-rise blocking layer, thereby reducing the voids of the moisture-rise blocking layer, thereby preventing the function of the moisture-rise blocking layer from decreasing. To include, the soil inlet barrier layer consisting of environmentally friendly materials to be decomposed after the role of soil inlet blocking for 2 to 3 years in the soil; Characterized in that the soil contaminated layer characterized in that to form a functional multilayer structure consisting of.

In addition, the neutralization and heavy metal rising barrier layer is composed of iron oxide, zeolite, and quartz as the main constituent minerals to have high neutralization ability to acid and the ability to remove heavy metals, and composed of fine particles with silt of 75% or more, and extremely low harmful elements. JGK ^® is used because of its low probability of causing environmental pollution.

In addition, the multi-layer soil recovery method using a soil barrier layer, the step of closely examining the soil site; After said step, determining whether the pollution of the site exceeds an environmental standard and whether it is transferred to plants; After the above step, if the environmental standard is exceeded or has been transferred to the plant, determining whether or not pollution is of high depth; Determining whether the contaminated soil can be restored to the topsoil improvement that improves the top of the soil after the step; After the above step, if the topsoil of shallow depth is contaminated and it is impossible to restore to the topsoil improvement, separate and excavate the contaminated topsoil and non-contaminated soil, fill the contaminated tops at the bottom, and install the contaminated soil blocking layer, Performing a first functional multi-story soil filling the soil back; After the above step, if the topsoil of shallow depth is contaminated but it is possible to restore to the topsoil improvement, it is possible to neutralize the contaminated soil and to suppress the increase of arsenic and hexavalent chromium due to the increase of pH and fertilization of phosphate fertilizer and the increase of toxicity. Mixing the selected functional additives with the soil of good quality to improve the soil soil in the functional soil; After the above step, derivation and fertilization of fertilization criteria in consideration of plant growth and heavy metal behavior; After the step, the completion and monitoring of the contaminated site restoration work; Including a functional multi-layer soil restoration method is configured.

In addition, the multi-layer soil recovery method using a soil barrier layer, the step of closely examining the soil site; After said step, determining whether the pollution of the site exceeds an environmental standard and whether it is transferred to plants; After the above step, if the environmental standard is exceeded or has been transferred to the plant, determining whether the contamination is a high depth; Determining whether the contaminated soil can be restored to the topsoil improvement that improves the top of the soil after the step; After this step, the soil was deeply polluted to restore the topsoil and neutralize the contaminated soil, and was selected as a material capable of suppressing the mobility and toxicity of arsenic and hexavalent chromium due to the increase of pH and fertilization of phosphate fertilizer. When it is impossible to improve the soil quality by mixing functional additives with high-quality soil, determining whether the elevation of the existing soil height is affected by irrigation, drainage, or access to agricultural machinery by covering soil; After the above step, if the elevation of the existing ground height due to cover does not become a problem, install the contaminated soil barrier layer on top of the contaminated soil, and build a non-contaminated soil of working depth on the contaminated soil barrier layer. A second functional multi-story soil step of raising the existing ground height; After the above step, derivation and fertilization of fertilization criteria in consideration of plant growth and heavy metal behavior; After the step, the completion and monitoring of the contaminated site restoration work; Including a functional multi-layer soil restoration method is configured.

In addition, the multi-layer soil recovery method using a soil barrier layer, the step of closely examining the soil site; After said step, determining whether the pollution of the site exceeds an environmental standard and whether it is transferred to plants; After the above step, if the environmental standard is exceeded or has been transferred to the plant, determining whether the contamination is a high depth; Determining whether the contaminated soil can be restored to the topsoil improvement that improves the top of the soil after the step; After the step, if the depth of contamination of the soil is deep and it is impossible to restore to the topsoil improvement, judging whether the elevation of the existing ground height by the soil is a problem for watering, drainage, or access to agricultural machinery; After the step, the rise of the existing ground height due to the cover is a problem, or install the contaminated soil barrier layer on top of the contaminated soil, the agent to fill a non-contaminated soil of working depth on top of the contaminated soil barrier layer 2 If it is difficult to restore to the functional multi-layer soil phase, the soil removed after removing the topsoil of the contaminated soil is reconstructed secondly for the contaminated soil removed or reclaimed in the neighboring tailings dump or waste landfill, and the top of the topsoil is removed. Installing a contaminated soil blocking layer and covering the non-contaminated soil on the contaminated soil blocking layer to form a soil layer; After the above step, derivation and fertilization of fertilization criteria in consideration of plant growth and heavy metal behavior; After the step, the completion and monitoring of the contaminated site restoration work; Including a functional multi-layer soil restoration method is configured.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. Prior to this, terms or words used in the specification and claims should not be construed as having a conventional or dictionary meaning, and the inventors should properly explain the concept of terms in order to best explain their own invention. Based on the principle that can be defined, it should be interpreted as meaning and concept corresponding to the technical idea of the present invention.

Therefore, the embodiments described in the specification and the drawings shown in the drawings are only the most preferred embodiment of the present invention and do not represent all of the technical idea of the present invention, various modifications that can be replaced at the time of the present application It should be understood that there may be equivalents and variations.

Hereinafter, referring to FIGS. 1 to 5, a soil contaminant blocking layer and a functional multilayered soil restoration method using the same according to an exemplary embodiment of the present invention will be described.

As shown, the contaminated soil barrier layer according to the present invention and the functional multi-layer soil restoration method using the same are the improvement of the soil volume by reducing the contaminated soil by using additives for the stabilization and neutralization of cationic and anionic heavy metals with high quality soil. In case of soil contaminated with high depth so that the contaminated soil is not restored by the improvement of the volume of soil, the soil is separated by using a contaminated soil barrier layer, thereby increasing hydrogen ions, heavy metals, and water by capillary action. The present invention relates to a contaminated soil blocking layer and a contaminated soil restoring method for effectively blocking the soil, and to neutralize and raise heavy metals (21), a moisture rise blocking layer (22), a soil inflow blocking layer (23), and a contaminated soil blocking layer (20). ).

1 is a structural diagram showing a contaminated soil blocking layer according to the present invention. As shown in the figure, the contaminated soil blocking layer 20 is a non-contaminated soil 30 located above the contaminated soil 10 from the contaminated soil. It has a functional multilayer structure that blocks the rise of pollutants (hydrogen ions, heavy metals) and moisture that rise to).

The contaminated soil blocking layer 20 is composed of a three-stage layer integrally formed with a neutralization and heavy metal rising barrier layer 21, a moisture rise barrier layer 22, and the soil inlet barrier layer 23 from the bottom.

Briefly described, the lowest neutralization and heavy metal rising barrier layer 21 serves to neutralize the hydrogen ions (H ⁺ ) rising from the contaminated soil and to adsorb and precipitate heavy metals.

In addition, the moisture rise blocking layer 22, which is an intermediate layer, is a layer that blocks the rise of water due to the capillary phenomenon.

In addition, the top earth and sand inlet blocking layer 23 is a layer that protects the intermediate layer, the water rise blocking layer 22 to prevent the shrinkage of the voids from the top of the earth from the top.

That is, as shown in FIG. 1, the contaminated soil blocking layer 20 is positioned in the middle of the contaminated soil 10 located below and the non-contaminated soil 30 located above.

With reference to this, it will be described in detail the neutralization and heavy metal rising barrier layer 21, the moisture barrier layer 22 and the soil inlet barrier layer 23 constituting the contaminated soil barrier layer 20.

The neutralization and heavy metal rising barrier layer 21 is the lowermost layer of the soil contaminant blocking layer 20, and the hydrogen ions and heavy metals rising from the contaminated soils 10 and 10 'located below by capillary action or groundwater level rise. Since it must be effectively blocked, it is desirable to formulate the upper part of the contaminated soil 10, 10 'by using a material having a high neutralization ability to the phase and adsorption and precipitation ability of heavy metals.

In the formation of the neutralization and heavy metal rising barrier layer 21, it is also preferable to use JGK ^® having high neutralization ability and heavy metal removal ability for acid developed in a previous study of the Korea Institute of Geoscience and Mineral Resources, a leading research institute. ^® is an inexpensive environmental material with iron oxides, zeolites and quartz as the main constituent minerals, with silt particles of more than 75%. As a result of the chemical composition analysis of Korea Institute of Geoscience and Mineral Resources, there are very few harmful elements, so the probability of causing environmental pollution is very low.

Table 1 shows the JGK ^® mineral composition, particle size distribution, and the ability to neutralize contaminant removal ability (KIGAM, 2006).

TABLE 1

Mineral composition Particle size distribution For mountains Neutralization ability Super Contaminant Adsorption PO ₄ ^{3 -} Pb CD As (Ⅲ) As (Ⅴ)  hematite, zeolite, calcite, quartz  clay: 2.29% silt: 75.04% sand: 22.67% Neutralization amount of JGK ^® 1g pH3 sulfuric acid solution = 3.5ℓ  ----------------- mg / kg -----------------  5868  21505  26385  15649  3017

<Table 1: Mineral composition, particle size distribution, neutralization capacity and pollutant removal capacity of JGK ^® : KIGAM, 2006>

The constant water rise blocking layer 22 is a layer for blocking the rise of water due to the capillary phenomenon, the rise of water due to the capillary phenomenon is dependent on the inner diameter of the capillary tube, the capillary height can be expressed by the following equation (Scott, 2000) .

h = 2ycosθ / ρgγ -------------------- [Equation 1]

(h: capillary rise (m), y = liquid-air surface tention (J / m ² ),

θ = contact angel, ρ = density of liquid (kg / m ² ),

g = acceleration due to gravity (m / s ² ), γ = radius of tube (m))

Using y = 0.0728 J / m ² at 20 ° C., θ = 20 °, ρ = 1000kg / m ² and g = 9.8m / s ² , it can be simplified to the following equation.

h = (1.4 × 10 ^-5 ) / γ --------------------- [Equation 2]

Soil voids and capillary heights are inversely proportional, and capillary heights varying in particle size are as follows (OMAF, 1973).

That is, the method for blocking the water and contaminants rising from the contaminated soil (10, 10 ') located in the lower portion by the capillary phenomenon lowers the capillary tube by installing a water rise blocking layer (22) with a large pore material Is possible.

Table 2 shows the capillary height according to the size of the particles.

TABLE 2

Texture Capillary  rise ( cm ) Texture Capillary  rise ( cm ) Very coarse sand 2.0 Fine sand 17.3 Coarse sand 4.1 Silt 101.6 Medium sand 8.1 Clay 〉 101.6

Table 2: Capillary heights varying in particle size

For reference, a capillary phenomenon is also called a capillary phenomenon, and the liquid level becomes concave or convex due to the difference between the cohesive force of the liquid and the adhesion force between the tube and the liquid. The concave is because the adhesion is stronger, and the convex is because of the stronger cohesion, and in either case it is in equilibrium with gravity when the height h = 2ycosθ / ρgγ of the liquid level inside and out.

This relationship is used to find the surface tension from the measured value of the contact angle of rising or falling of the liquid level. The surface curved by capillary phenomenon is called meniscus. If the surface is concave, the liquid level in the tube becomes high (if water), and if the surface is convex, the liquid level in the tube is low (if mercury).

This phenomenon is one of the natural phenomena that can be seen frequently. The reason why water penetrates the absorbent paper or cloth by itself is because the fibers of the absorbent paper or cloth serve as capillary tubes to suck up the water. This phenomenon is also caused by the spread of moisture and nutrients absorbed from the roots of plants throughout the plant.

When the back of the water rise blocking layer 22 is simply filled with non-contaminated soil (30, 30 '), the earth and sand are moved to the water rise blocking layer 22 at the bottom to reduce the size of the pores so that the water rise blocking layer ( 22) There is a risk of loss of function.

Therefore, it is necessary to install a water-permeable membrane to prevent the soil inflow into the moisture rise blocking layer 22. The soil inflow blocking layer 23 according to the present invention is to do that.

If permeable membranes exist to prevent soil infiltration for a long time without deterioration in the soil, the permeability and permeability of the soil will be deteriorated, which will adversely affect the growth of crops. The installation of a permeable membrane is preferable, and in general, the soil is stabilized about 1 year after being physically disturbed and the movement of particles is extremely small. Therefore, when a permeable membrane is naturally decomposed after one year or more in the soil, it is to prevent the deterioration of physical properties that adversely affect crops and at the same time to maintain the voids in the moisture barrier layer 22.

That is, it is preferable that the soil inflow blocking layer 23 according to the present invention is environmentally friendly and selects a material that is decomposed after acting as a soil inflow blocking role for two to three years in the soil.

2 is a first schematic view of the functional multi-story soil restoration method according to the present invention, a shallow depth of soil as shown in the figure is a method that is carried out on the site difficult to achieve the restoration goal by the functional soil improvement.

The functional volume improvement mentioned above is a step S150 to be described below, which is selected as a material capable of neutralizing the contaminated soil and suppressing the increase in mobility and toxicity of arsenic and hexavalent chromium due to a rise in pH and fertilization of phosphate fertilizers. Refers to the mixing of functional additives with quality soil.

FIG. 2 is a first functional multi-layer soil construction method to insulate the topsoil 11 and the bottom of the non-polluted soil 30 to securely isolate the topsoil 11 to the bottom.

After separating and excavating the contaminated soil 11 and the non-contaminated soil 30, the contaminated soil 11 is filled in the lower portion, and then the contaminated soil blocking layer 20 described above in FIG. 1 is installed. 30 is backfilled with the soil blocking layer 20 above.

3 is a second schematic diagram of a functional multi-layer soil restoration method according to the present invention, as shown in the figure, the depth of soil deep, as shown in the figure, the restoration target achievement to the topsoil improvement using the functional soil improvement technique described in FIG. Although it is difficult, it is a construction method for restoration work on sites where land use does not cause problems due to changes in the form of use of land, and the opinions of farmers (owners and owners).

3 is a second functional multi-layer soil method for installing a contaminated soil blocking layer 20 on a contaminated soil 10 and depositing a non-contaminated soil 30 having a working depth (50 cm).

By applying this method, it will be raised about 60cm (50cm of soil layer and 10cm of barrier layer) from the existing ground height of the site. Since the elevation of arable land elevation may cause various problems such as watering and drainage, it may be preferable that the construction method as shown in FIG. 3 be performed under the consent of farmers (owners and occupants).

Figure 4 is a third schematic diagram of the functional multi-layer soil restoration method according to the present invention, as shown in the figure is deep soil depth and top soil improvement or non-contaminated soil of soil depth on the top of the soil contaminated layer described in Figure 3 Restoration is also a method that applies to difficult contaminated sites.

That is, Figure 4 removes the top soil of the soil 10 of the contaminated soil (10, 10 '), and install the contaminated soil barrier layer 20 on the contaminated soil (10') and then the contaminated soil barrier layer (20) It is a third functional multi-layer soil construction method that forms a soil layer (50 cm) with non-polluted soil 30 on the top. The top soil, that is, the contaminated soil 10 of the contaminated soil 10, 10 ′ is removed about 60 cm (soil layer and contaminated soil blocking layer), and the removed contaminated soil 10 is disposed in a nearby tailings storage or waste landfill. Naturally, the secondary restoration method should be applied to the contaminated or removed soil 10.

5 is a flow chart of a functional multilayer loam restoration method according to the present invention. As shown in the drawing, FIG. 2, 3, and 4 show the schematic diagram of the functional multilayer loam.

Pollution site inspection step (S100) to investigate soil pollution concentration and range (depth / area), plant contamination, surrounding environment, risk, groundwater pollution / flow, pollutant discharge, related laws, local residents and land owner opinions After passing through the step (S100), the result of exceeding the environmental standard or whether the plant has been transferred to the step (S110), and after the step (S110), otherwise (NO) using the soil restoration method Completion of the contaminated site restoration work and ends with the monitoring step (S200), but if the transition to the plant (YES) to go through the step (S120) to determine whether the high-depth pollution (~ 60cm).

After the step (S120), if it is not a high-depth pollution, go through the target achievement step (S130) for restoring to the topsoil improvement of the top layer of soil, if possible (YES) functional floor improvement step (SES) of the soil topsoil (S150). But if it is impossible (NO) to go to the first multi-layer multi-level soil (S140) process is carried out as shown in FIG.

In addition, in the case of high-depth contamination, after going through the target achievement step (S130) for restoring to the topsoil improvement, which is also the upper part of the soil layer, if possible (YES), the functional soil improvement step (S150) of the soil topsoil is passed. If not (NO), a step (S160) of determining whether there is a ground level problem due to covering is performed. (The above ground level rising problem is described above.)

After the step S160, if there is a problem (YES), the method of the third functional multi-layer coating step S180 as described in FIG. 4 is used, but if there is no problem (NO) the same as described in FIG. The method of the second functional multi-layer soil layer (S170) is used.

For reference, in the step (S120) of measuring the high-depth contamination, 60 cm, which is the maximum depth of the field volume improvement using the tractor rotor ring, was applied.

Reconstruction method using the functional multi-layer soil cover step (S140, S170, S180) described in Figures 2, 3, 4 and the step of implementing the functional soil improvement (S150) of the contaminated soil all considered plant growth and heavy metal behavior Fertilization criteria derivation and fertilization stage (S190) and the contaminated site restoration construction using the soil restoration method is completed and monitored (S200).

Explaining the application of fertilization management criteria applied to the step S190, the growth of crops and heavy metal contamination depends on the soil pollution characteristics (concentration, presence form, plant availability), organic matter content, nutrient direct degree, physical properties. Fertilization has a great influence on the growth of plants and the behavior of heavy metals in the soil. Therefore, fertilization needs to be done with caution on the site where the contaminated soil is improved by landfill method.

In particular, phosphate fertilizer stabilizes heavy metals such as Pb, Cd, Zn, and Cu in soil to reduce toxicity, mobility and plant availability, while heavy metals that form anionic complexes such as As and Cr are desorbed from soil particles. Increasing plant availability. Therefore, fertilizer fertilizers should be set according to the type, concentration, and type of heavy metals present in the soil.

In addition, the functional multi-layer soil recovery step (S140, S170, S180) that separates the contaminated soil underneath creates a soil layer with high-quality, uncontaminated soil. Generally, the soil used in the restoration site has a high content of organic matter and nutrients. Use a lot of low soil.

Therefore, about two to three years after completion of restoration work, plant growth tends to be disadvantageous. Since the Rural Development Administration sets and applies criteria for organic matter content, effective phosphorus, and effective silicic acid on the soil of the site, the application is based on the physicochemical properties of the soil material (quality soil and additives) and the RDA standard. It would be desirable to determine the criteria.

Table 3 below shows the physicochemical characteristics of recommended agricultural land soil.

division standard Physical properties Clay content: 15% Chemical properties pH: 6.0 ~ 6.5, organic matter content: 20 ~ 30g / kg   Nutritional status  Effective Phosphoric Acid: 300 ~ 500 mg / kg, Substitutable K: 0.5 ~ 0.6 mg / kg, Substitutable Ca: 5 ~ 6 mg / kg, Substitute Mg: 1.5 ~ 2.0 mg / kg

<Table 3. Physicochemical Characteristics of Soil Recommended for Rural Development Administration>

As described above, although the embodiments of the present invention have been described with reference to the accompanying drawings, the present invention is not limited thereto and is intended by those skilled in the art to which the present invention pertains. Various modifications and changes may be made without departing from the scope of the appended claims.

As described above, the present invention is to reduce the pollution concentration for dilution by using a functional soil material consisting of high quality soil and additives to inhibit plant transition, neutralization, and secondary environmental pollution prevention of heavy metals by additives. It is effective.

In addition, the present invention is to isolate the contaminated soil from the bottom to the contaminated soil, contaminated soil barrier layer, non-contaminated soil layer in order to effectively block the hydrogen ions, heavy metals, and water rising by the capillary phenomenon to safely isolate the contaminated soil at the bottom In addition, it has the effect of securing the stabilization of heavy metals, preventing plant metastasis and promoting growth in the topsoil restored by functional soil improvement.

Claims (5)

Non-contaminated soil 30 is deposited on top of the contaminated soil 10, 10 'to safely isolate the contaminated soil 10, 10', between the contaminated soil 10, 10 'and the non-contaminated soil 30. In order to effectively block the rise of contaminants such as hydrogen ions, heavy metals and water rising from the contaminated soil (10, 10 ') to the non-contaminated soil (30), A neutralization and heavy metal rising barrier layer 21 positioned above the non-contaminated soil 30 to effectively block hydrogen ions and heavy metals rising from the contaminated soils 10 and 10 'under the capillary phenomenon or the groundwater level; ); Located above the neutralization and heavy metal rising barrier layer 21, the water rise to lower the capillary height by forming a large pore material to block the water and contaminants rising from the contaminated soil (10, 10 ') by the capillary phenomenon A barrier layer 22; The water rise blocking layer 22 is located above, the soil is introduced into the air gap formed in the water rise blocking layer 22, the air gap of the water rise blocking layer 22 is reduced by the function of the water rise blocking. A sediment inflow barrier layer 23 including a function of a permeable membrane to prevent deterioration, and composed of environmentally friendly materials so as to be decomposed after acting as a soil inflow block for 2 to 3 years in soil; Soil blocking layer characterized in that it has a functional multilayer structure. The method of claim 1, The neutralization and heavy metal rising barrier layer 21 is iron oxide, zeolite, quartz are the main constituent minerals to have a high neutralization ability to acid and the ability to remove heavy metals, the silt is composed of fine particles of more than 75%, harmful elements Soil barrier layer is characterized in that JGK ^® is used, which is present in a very small amount, causing low pollution. In the functional multi-layer soil restoration method using the contaminated soil barrier layer formed in claim 1, Closely inspecting the contaminated site (S100); After the step (S100), the step of determining whether the pollution of the soil exceeds the environmental standards and whether the transition to the plant (S110); After the step (S110), if the environmental standards or when the transition to the plant, the step (S120) to determine whether the contamination is high depth; After the step (S120), the step of determining whether the contaminated soil can be restored to the topsoil improvement to improve the top of the soil (S130); After the step (S130), if the topsoil of shallow depth is contaminated, and it is impossible to restore to the topsoil improvement, after contaminating and separating the contaminated topsoil 11 and the non-contaminated soils 30 and 30 ', the contaminated topsoil 11 Filling the lower portion and installing the contaminated soil blocking layer 20 and then performing a first functional multi-layer soil filling the non-contaminated soil amount 30 on the upper portion (S140); After the step (S130), if the topsoil of the shallow depth is contaminated but can be restored to the topsoil improvement, neutralize the contaminated soil (10, 10 '), mobility of arsenic and hexavalent chromium by the pH rise and fertilizer of phosphate fertilizer (150) functionally reclaiming the contaminated soil (10, 10 ') by mixing a functional additive selected as a material capable of suppressing an increase in toxicity and soil with high-quality soil; After the step (S150), derivation and fertilization of the fertilization criteria in consideration of the growth and heavy metal behavior of the plant (S190); After the step (S190), the step of completing the pollution site restoration work and monitoring (S200); Functional multi-layer soil restoration method, characterized in that configured to include. In the functional multi-layer soil restoration method using the contaminated soil barrier layer formed in claim 1, Closely inspecting the contaminated site (S100); After the step (S100), the step of determining whether the pollution of the soil exceeds the environmental standards and whether the transition to the plant (S110); After the step (S110), if the environmental standards or when the transition to the plant, the step (S120) to determine whether the contamination is high depth; After the step (S120), the step of determining whether the contaminated soil can be restored to the topsoil improvement to improve the top of the soil (S130); After the step (S130), the depth of contamination of the soil is deep, neutralizing the restoration to the topsoil improvement and contaminating soil (10, 10 ') and increasing the mobility and toxicity of arsenic and hexavalent chromium due to the increase of pH and fertilization of phosphate fertilizers. If the functional additives selected as the material capable of suppressing the mixing with the high-quality soil and the step 150 for the functional improvement of the contaminated soil (10, 10 ') are impossible, the elevation of the existing ground height by irrigation is irrigation and drainage. Or determining whether there is a problem in the site utilization (S160); After the step (S160), if the elevation of the existing ground height due to the cover does not matter, install the contaminated soil blocking layer 20 on top of the contaminated soil (10, 10 '), and the contaminated soil blocking layer A second functional multi-story soil step (S170) to allow the soil to rise above the existing ground height by filling the non-contaminated soil 30 of the working depth on the upper portion of the 20; After the step (S170), derivation and fertilization of the fertilization criteria in consideration of the growth and heavy metal behavior of the plant (S190); After the step (S190), the step of completing the pollution site restoration work and monitoring (S200); Functional multi-layer soil restoration method, characterized in that configured to include. In the functional multi-layer soil restoration method using the contaminated soil barrier layer formed in claim 1, Closely inspecting the contaminated site (S100); After the step (S100), the step of determining whether the pollution of the soil exceeds the environmental standards and whether the transition to the plant (S110); After the step (S110), if the environmental standards or when the transition to the plant, the step (S120) to determine whether the contamination is high depth; After the step (S120), the step of determining whether the contaminated soil can be restored to the topsoil improvement to improve the top of the soil (S130); After the step (S130), if the depth of contamination of the soil is deep, and the restoration to the topsoil improvement is impossible, the step of determining whether the rise of the existing ground height by the cover soil is a problem for the watering, drainage or access of agricultural machinery (S160) )Wow; After the step (S160), the rise of the existing ground height due to the cover is a problem, or install the contaminated soil blocking layer 20 on top of the contaminated soil (10, 10 '), the contaminated soil blocking layer ( 20) If it is difficult to restore to the second functional multi-layer soil stage (S170) that fills the soil depth of non-contaminated soil in the upper part of the soil, the soil removed after removing the topsoil of the contaminated soil 10 is placed in a nearby tailings storage or waste landfill. Secondary restoration is performed on the contaminated soil removed or buried, and the contaminated soil blocking layer 20 is installed on the top of which the topsoil is removed, and the non-contaminated soil 30 is covered on the contaminated soil blocking layer 20. A third functional multi-layer soil step (S180) to form a soil layer; After the step (S180), derivation and fertilization of the fertilization criteria in consideration of the growth and heavy metal behavior of the plant (S190); After the step (S190), the step of completing the pollution site restoration work and monitoring (S200); Functional multi-layer soil restoration method, characterized in that configured to include.

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