KR100952845B1 - Method for Remediation of Contaminated Soil Applying to Fracture-permeation and Inspecting State Thereof - Google Patents

Abstract

  The present invention relates to a method for purifying soil and checking the state of pollution by applying soil pore enlargement, and includes a liquid slurry including a sand proppant, a guar gum and water mixture, and a contaminant treatment additive. It is pumped to the underground soil by pumping at a high pressure greater than the pressure, the surface slope of the soil changed by the liquid slurry sprayed to the underground soil is measured by a plurality of geophysical tiltmeter, the measured tilt information is data And then drawing the base into a three-dimensional image. The present invention crushes the soil, expands the voids, delivers the pollutant treatment additives thereto, and accurately cleans the contamination of the soil in the underground soil through a series of processes in which three-dimensional images of the surface change information are databased. It is easy to grasp. In addition, the present invention can solve the conventional problem that the contaminant treatment additive is not well delivered by injecting the contaminant treatment additive together when expanding the voids.

Soil contamination, viscous fluid, inclinometer

Description

Method for Remediation of Contaminated Soil Applying to Fracture-permeation and Inspecting State Thereof}

The present invention is an in-situ treatment technology for the pollution and purification of soil and groundwater, and more particularly, a method for purifying soil contamination and confirming the contamination state. More specifically, the soil purification process is performed through the entire process of crushing the soil to expand the voids, injecting and conveying contaminant treatment additives, and subjecting the surface change information to a three-dimensional image based on the database. It is easy and accurate to figure out.

Conventionally, the underground treatment method for the purification of soil or groundwater contamination is to inject specific pollutant treatment chemicals through ground well monitoring or injection wells, especially in the case of fine soils There are limitations in effectively dispensing and dispensing drugs, and therefore, it is not possible to determine the distribution or efficiency of the injected drugs and the state of purification of contaminants.

Therefore, in order to measure the efficiency of polluting the underground soil by the pollutant treatment agent, a sample is collected through a groundwater monitoring well installed around the polluted area before and after the injection of the pollutant treatment agent and after a predetermined time. I had to analyze it.

In addition, there was no way to know whether the pollutant treatment agent was correctly injected into the desired location of the underground soil. Therefore, if the pollutant was not properly cleaned, the problem of having to inject the pollutant treatment medicine again after such a time has elapsed. There was this.

Accordingly, the present invention is to solve the above problems, to create a pore network by crushing the soil, and to pass the pollutant treatment additives, and to a series of three-dimensional imaging process of the surface change information according to the database In addition, the present invention is to provide a new soil contamination purification and pollution status checking method that can accurately and simply identify the pollution situation in the underground soil. In addition, an object of the present invention is to solve the problem that the contaminant treatment additive is not well delivered after the generation of voids, and to provide a method for more effectively purifying contaminants.

In order to achieve the above object, a method of purifying soil and checking the state of soil according to the present invention includes a liquid slurry including a sand proppant, a guar gum and water mixture, and a contaminant treatment additive as an underground soil crusher. Pumping to an underground soil by pumping it to a high pressure greater than the ground pressure, thereby creating voids in the underground soil and simultaneously delivering the contaminant treatment additive to the created voids; Measuring the surface slope of the soil changed by the liquid slurry injected into the underground soil with a plurality of geophysical tiltmeters installed on the ground surface, and databaseting the measured tilt information; And drawing the location of the pollutant treatment additive distributed in the underground soil in a two-dimensional or three-dimensional image using the database wreath slope information.

Here, the contaminant treatment additive may be one or more selected from solid carbon or nutrient materials, abiotic treatment agents, abiotic and biological treatment agents and high viscosity or semisolid treatment agents.

In addition, after the drawing step, the present invention measures the slope of the surface of the soil that is changed by the pollutant of the underground soil by the pollutant treatment additive, and monitors the pollution purification state using the measured slope information It may be to include the step further.

Further, after the drawing step, re-injecting the liquid slurry in the underground soil, measuring the surface slope by the re-injection, and drawing the location of the contaminant treatment additive using the measured slope information It is preferable to further include; In addition, the present invention may further comprise the step of delivering a separate contaminant treatment additive to the generated voids through the groundwater pipe embedded in the underground soil.

Specific details of other embodiments are included in the detailed description and the drawings.

The present invention as described above expands the pores by crushing the soil, injects and delivers the contaminant treatment additive thereto, and cleans the contamination in the underground soil through a series of whole processes of stereoscopic imaging of the change information of the ground surface accordingly. Can be identified accurately and simply. In addition, the present invention can solve the problem that the liquid slurry for pore expansion includes a contaminant treatment additive together, so that the contaminant treatment additive is not well injected after delivery.
In addition, the present invention can more effectively purify contaminants by using various treatment additives as contaminant treatment additives.

Hereinafter, one preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings. The invention may be better understood by the following examples, which are intended for purposes of illustration of the invention and are not intended to limit the scope of protection defined by the appended claims.

1 is a flowchart illustrating a process of a method for purifying soil and checking a state of pollution according to the present invention, and as shown herein, the present invention includes a step of setting a pollution area (S100); Spraying a liquid slurry into the soil of the contaminated area to generate voids, and transferring the contaminant treatment additive to the generated pores (S110); Measuring the slope of the ground surface of the soil changed by the sprayed liquid slurry, and databaseting the measured slope information (S120); Drawing a location of a contaminant treatment additive using the databased slope information (S130); And monitoring the contamination purification state (S140).

The present invention generates the pore network by crushing the soil, delivers the pollutant treatment additive thereto, and accurately corrects the pollution situation in the underground soil through a series of processes for stereoscopic imaging of the surface change information. It is to figure out simply.

First, the present invention may optionally include a step of setting a contaminated area including a contaminant layer (S100) before the specific purification of the soil and the purification of the soil. This is to establish a specific contaminated area to purify the contaminants, and to determine the size, depth, and direction of movement of the contaminant layers in the basement, prior to preventing the contaminant base containing contaminants from spreading to other areas. FIG. 2 shows a salt contamination area that exemplarily shows the location of the crush injection inlet selected for purification of contamination. Such a contaminated area setting (S100) may be set by a user who wishes to carry out the present invention, or may be determined by a predetermined setting device suitable for performing this.

Then, the liquid slurry is injected into the soil of the contaminated area to generate voids, and the contaminant treatment additive is transferred to the generated pores (S110). That is, a liquid slurry containing a sand proppant, a guar gum and water mixture, and a contaminant treatment additive is pumped to an underground soil by pumping it to a high pressure greater than the ground pressure by an underground soil crusher, and thereby underground At the same time as creating voids in the soil, the contaminant treatment additive is delivered to the created voids.

The liquid slurry includes a sand jet and a viscous fluid. The sand jet is pumped at a high pressure and flow rate that is stronger than the ground pressure and the soil layer strength through the injection well or the injection pipe of the underground soil crusher. The soil is broken up to create voids, and the viscous fluid is intended to transport such sandblasts. As the viscous fluid, environmentally and biodegradable polysaccharides are preferable.

In addition, the liquid slurry according to the present invention includes a contaminant treatment additive, and the contaminant treatment additive may be various additives capable of purifying contaminants in the underground soil. The injection of such contaminant treatment additives into the soil and the state of injection are related to the particle diameter of the additive to be injected, in particular depending on the size of the voids formed by the spacing between the soil particles. If the particle diameter of the contaminant treatment additive is larger than the void inlet formed by the sandblasting body, the contaminant treatment additive will be provided only in the space physically crushed by the injection well or the injection tube, but the particle diameter of the contaminant treatment additive is If it is smaller than the void inlet formed by the sand blast, the contaminant treatment additive will be sprayed into the soil through the micro voids formed by the sand blast.

Therefore, in the case where the air gap is first formed in the underground soil by the hydraulic crushing method or the pressure penetration injection method, and then the contaminant treatment additive is injected into the air gap thus formed, the inlet of the formed air gap becomes small so that Could not inject contaminant treatment additives widely. Accordingly, the present invention includes a sand jet in a liquid slurry for forming voids in the underground soil and a viscous fluid for transporting the same, and in particular, the liquid slurry includes an additive for treating contaminants, thereby providing a treatment agent. It is characterized in that it is delivered to the generated pores at the same time as the pores generated.

In other words, in the boring hole bored through the injection well or the injection pipe to crush the soil, the underground soil crusher uses a special spraying device and an injection pump to hydraulically crush the liquid slurry containing the sand jet and the viscous fluid. When it is pushed out by the method and the pressure penetrating injection method, voids are formed in the underground soil by the sand jet, wherein the contaminant treatment additive contained in the liquid slurry moves to the formed pores and comes into contact with the contaminated soil. will be. In other words, if there is a small time gap between the formation of voids and the injection of contaminant treatment additives, or if you simply want to inject the contaminant treatment additives through a spray well or spray tube without a sand jet, the contaminant treatment additives in the case of fine soils are the pores of the soil. In the case of injecting a liquid slurry containing a sand jet and a contaminant treatment additive at a pressure greater than the ground pressure as in the present invention, the voids become large due to the pressure inside the underground soil, thus creating By delivering the contaminant treatment additive directly to the pores, the contaminant treatment additive can be easily injected in a wider range.

3 is a schematic diagram showing a state in which the pollutant treatment additive is injected into the underground soil according to the present invention, which includes soil crushing pores generated from the wells of the underground soil crusher into the stratum and contaminants delivered with the same. Treatment additives are shown in the form of yellow branches. For reference, the hydrocabons and solvents formed in the strata are examples of contaminants.

Ultimately, the present invention is intended to more effectively deliver various contaminant treatment additives in solid, liquid or slurry form to contaminated areas using soil crushing and pressure penetrant injection techniques, and another feature of the present invention is such contaminant treatment additives. By using a variety of treatment additives it is to more effectively purify contaminants. That is, according to the present invention, as the contaminant treatment additive included in the liquid slurry, various solid carbon or nutrient materials, abiotic treatment agents, abiotic and biological treatment agents, high viscosity or semisolid treatment agents, etc. may be selected and used. Can be.

For example, the solid carbon or nutrient material may include shellfish and shellfish derivatives including chitonaceous materials, purified chitin, chitosan or other chitin-containing substances, and the like, cellulose-containing substances, sugars or starch-containing solid powders, and foods. Derivatives (eg sugar beet wastes, potato waste, etc.), sugars or polysaccharide complexes, and DARAMEND.TRM and TERRAMEND.TRM from Adevntus Americas, USA. In addition, the non-biological treatment agents include reactive metals or metal complexes, for example, noble iron (nanometer size or powder iron), two metal irons (nanometer size two metal irons), and permanganese (potassium and sodium). And oxidants such as persulfates. Also specific examples of such non-biological and biological complex treatments are EHC ^™ products from Adevntus Americas, USA. In addition, examples of the highly viscous liquid or semi-solid treatment product, for example, HRC.TRM ORC.RTM, HRC-X ^TM , MRC ^TM Related products (US Regenesis), vegetable oil and molasses.

The present invention utilizes a hydraulic soil pore crushing technique and a pressure penetrating spraying technique, as well as low permeability fine soil, high, medium permeability sand or silt soil, solid, slurry or liquid solution type of contaminant treatment additives It is to provide a three-dimensional drawing technology that can confirm the distribution of contaminant treatment additives while providing innovative, economical, environmentally-friendly / sustainable development of environmental pollution by effectively delivering and distributing it to contaminated layers.

The present invention for this purpose is to spray the liquid slurry as described above to create the pores, and after passing the step (S110) of transferring the pollutant treatment additive to the generated pores, the surface of the soil is changed by the sprayed liquid slurry The slope is measured, and the measured slope information is converted into a database (S120).

One of the biggest problems in the conventional ground pollution purification technology is that it is not possible to confirm the effect of the pollutants being purified. This is because it was not possible to visually check the state of pollution purification in which the treatment proceeds inside the underground soil. Therefore, in order to confirm the contamination purification state, the only method was to collect a sample by digging underground soil in anticipation of the area where the pollutant treatment additive was distributed.

Accordingly, in the present invention, by measuring the surface slope of the soil changed by the liquid slurry sprayed to the underground soil, by measuring a number of geophysical tiltmeter (geophysical tiltmeter) installed on the surface, and by the database of the measured tilt information In addition, this study attempted to accurately and simply identify the pollution situation in the underground soil.

4A and 4B are schematic diagrams showing examples of the surface warpage phenomenon and the inclination diagram according to the ground tilt measurement principle of the geophysical inclinometer according to the present invention, respectively. The geophysical inclinometer is a device for recording fine movements of the earth's surface, and the present invention uses the inclinometer to measure soil surface slope by detecting vibrations and soil changes in the ground and soil, which are changed by the liquid slurry. In addition, the information on the distribution of the crushed soil layer and the pollutant treatment additives delivered therein is made into a DB, which is then used for various information including three-dimensional drawing. This technique can be called Tiltmeter Geophysical Mapping (TGM), a fast, reliable, non-destructive and sophisticated method.

 Specifically, the above method utilizes a technique of observing fine movements of the earth's surface in a sensing device (ie, geophysical inclinometer) attached to the ground when a liquid slurry containing a contaminant treatment additive is injected into the underground soil. For example, twelve to twenty-five geophysical inclinometers attached to the earth's surface are networked or centrally arranged around the underground perforations for fracture. The spacing and configuration of the geophysical inclinometers is determined by how many and how deep the perforations are to be broken. The tilt of the fracture ground surface is measured at each tiltmeter station, and the measured tilt information is analyzed and understood on the basis of the principle of tiltmeter geophysics and made into a database.

Subsequently, in the method of purifying the soil and checking the state of pollution according to the present invention, the method may further include drawing a position of the pollutant treatment additive distributed in the underground soil in a two-dimensional or three-dimensional image using the database-based gradient information ( S130). This is to plot the change of the tilt signal information measured by the geophysical inclinometer in the real underground soil according to geophysical modeling in a two-dimensional or three-dimensional image.

That is, the slope information measured in step S120 is a geographic information system (Geographycal).
Information Systems (GIS) technology is used to coordinate the location of liquid slurries (including contaminant treatment additives) distributed in underground soil. Geographic Information System (GIS) technology is an excellent technology for visualizing geographic and environmental information. In the present invention, existing software (eg ArcGIS® by ESRI) for performing such a technique can be used, and through this, the location of the pollutant treatment additive distributed in the underground soil can be visualized and imaged in two or three dimensions. The principle of GIS technology is to input all geographic and subterranean soil layers in the coordinates of the X, Y, and Z axes, and to place soil samplers, groundwater pipe measurements, soil shredding networks, and the location of injected liquid slurry (including contaminant treatment additives). It is to accurately database and output two-dimensional or three-dimensional drawings. In addition, by inputting a usable aerial photograph or satellite image, it is possible to implement a high-resolution three-dimensional stereoscopic drawing, which may be represented by contour lines on the ground surface. In addition, this technology can be implemented as a video, it is possible to provide a real-time visual status of pollution purification and processing progress.

FIG. 5 is a photograph showing the location of the pollutant treatment additive distributed in the underground soil using the slope information according to the present invention in a two-dimensional image, and as shown here, zero ferrous iron (FBH2A) as one of the pollutant treatment additives. In the case of using, it can be seen that the duct iron is distributed in the sand base layer formed by the fine clay soil and sand spray layer.

In addition, the GIS technology may receive various databaseized information and manage the geographic information in association with other technical data. This means that all data from the site, such as geological columnar, tiltmeter geophysics, and environmental sample analysis data, can be input to monitor the entire process. As such, it can be used as visual aids to help non-technologists understand the site and determine process accuracy.

Furthermore, after the drawing step (S130), the present invention measures the slope of the ground surface of the soil that is changed by purifying the contaminants of the underground soil by the pollutant treatment additive, and purifying the pollution using the measured slope information. It may further comprise the step of monitoring the state (S140). That is, not only the change of the surface created by the formation of voids by the liquid slurry, but also the contamination of the ground by measuring the change of the surface produced by actually purifying the contaminants in the underground soil by the pollutant treatment additive included in the liquid slurry. It is constantly checking the status. Measuring the slope of the ground surface of the soil, and monitoring the pollution purification state by using the measured slope information is replaced with the description in the above-described step S120 and S130.

Figure 6 is a three-dimensional picture of the pollution distribution shown by using a geographic information system technology, Figure 7 is a three-dimensional three-dimensional view picture showing a state in which the contaminants in the underground soil after the contamination treatment additive is injected in accordance with the present invention. . That is, FIG. 6 shows a state in which pollutants are distributed in a polluted area before the pollutant treatment additive according to the present invention is injected, and FIG. 7 shows a state of change of pollutants after the pollutant treatment additive according to the present invention is injected. will be. In the present invention, a pollution area to purify the pollution is determined on the basis of the pollution distribution picture as shown in FIG. 6, and after the pollutant treatment additive is injected according to the present invention to change the state of the pollutant, the change is shown in FIG. 7. It can be shown differently by the size of the circle as shown.

In addition, the present invention, after the drawing step (S130), the liquid slurry is re-injected in the underground soil, the surface slope by the re-injection is measured, using the measured slope information of the contaminant treatment additive It is also possible to further include; drawing the location. In other words, by repeatedly measuring the change of the surface created by the repetitive injection of contaminant treatment additives for contaminant purification, as well as the change of the surface created by the formation of voids by the liquid slurry, it is repeatedly confirmed the state of contamination purification. . Measuring the inclination of the ground surface of the soil and drawing the position of the pollutant treatment additive using the measured inclination information is replaced with the description in the above-described steps S120 and S130.

In addition, the present invention may further include the step of delivering the contaminant treatment additive to the generated pores through the groundwater pipe embedded in the underground soil in delivering the contaminant treatment additive to the generated pores. .
That is, the contaminant treatment additive is not injected into the injection well or the injection pipe of the underground soil crusher, but is additionally injected through another path. Contaminant treatment additives injected through such separate groundwater pipes under positive pressure may penetrate into the pores generated by the sandblast and increase contact area with contaminated soil and groundwater.

In summary, the present invention as described above,

1) maximization of mass transfer by direct injection of treatment additives;

2) By using hydraulic fracturing method, soil voids can be
Shortening the treatment time for soil contamination by optimizing the contact conditions between the salt and the purification chemicals;

3) cost and time efficiency as treatment additives are injected simultaneously with crushing; And

4) Accurately determine and verify the performance and effectiveness of the application of pollution purification technology by recording the data of the air gap network and the distribution of processed materials delivered in the above process in real time, and drawing them in three-dimensional detail with the drawing and geographic information system. It has the effect of making it possible, and the present inventors confirmed the effect and technical superiority through several pilot projects.

8 to 10 are graphs showing chemical state change state, volatile fatty acid formation and extinction state, and dehalogenation process after chitin is injected as a contaminant treatment additive according to the present invention, respectively. First, FIG. 8 shows the pollution treatment efficiency through various observation data for eight months after chitin was added to soil contaminated with chlorine hydrocarbon as a pollutant treatment additive. As shown here, it can be seen that the reduction treatment is performed efficiently by reducing the concentration of sulfate and increasing the concentration of methane. In the case of the underground treatment technique according to the prior art, the reductive treatment usually takes about 1 to 2 years, and the present invention shows that the contaminant treatment additive is effectively delivered. And, Figure 9 shows the generation and disappearance of the volatile fatty acid based on the data measured in the same field as the experimental conditions according to Figure 8, it can be seen that the volatile fatty acid is generated and disappeared in the groundwater at the same time in the reductive treatment Can be. In addition, Figure 10 shows the reductive dehalogenation process of halogen group aromatic organic substances after Chitin injection, the contaminant (TCE) is reductively decomposed, its decomposition products cis-DCE, VC is generated and decomposed again As a result, the pollutants are being changed to Ethene, which is a harmless substance. In the case of the underground treatment technology according to the prior art, the present invention shows good treatment efficiency in a short period of eight months, considering that the treatment period of the pollutant (TCE) takes several years (> 2, 3 years).

11 is a graph showing the dechlorination process after injecting ferrous iron as a contaminant treatment additive according to the present invention, and shows the reductive dechlorination process of carbon tetrachloride and chloroform in the groundwater after the injection of zero iron. According to this, it can be seen that in the case of injecting ferrous iron as a contaminant treatment additive according to the present invention, a remarkably excellent purifying effect can be achieved in 5 months.

The present invention has been invented to connect each of the detailed processes each of the inventors have developed, and is one process containing the entire process of pollution treatment, and demonstrated and confirmed the excellent effect as described above.

On the other hand, while the present invention has been shown and described with respect to certain preferred embodiments, the invention is variously modified and modified without departing from the technical features or fields of the invention provided by the claims below It will be apparent to those skilled in the art that such changes can be made.

The present invention includes a series of processes for crushing the soil to expand the voids, delivering the pollutant treatment additive thereto, and subjecting the surface change information to a three-dimensional image of the ground surface. It is possible to provide a new way to clean up the soil and to determine its status.

1 is a flowchart illustrating a process of a method for purifying soil and checking a state of pollution according to the present invention.

FIG. 2 is a map photograph of a salt contamination area illustratively showing the location of a crushing injection inlet selected for pollution purification according to the present invention;

3 is a schematic diagram showing a state in which the pollutant treatment additive is injected into the underground soil according to the present invention,

4A and 4B are schematic diagrams illustrating examples of the surface warping phenomenon and the inclination diagram according to the ground tilt measurement principle of the geophysical inclinometer according to the present invention.

FIG. 5 is a photograph illustrating a location of a contaminant treatment additive distributed in an underground soil using a tilt information according to the present invention in a two-dimensional image.

6 is a three-dimensional pollution distribution photograph shown using a geographic information system technology,

7 is a three-dimensional stereoscopic photograph showing a state in which the contaminants in the underground soil are purified after the contaminant treatment additive is injected according to the present invention.

8 to 10 are graphs showing changes in chemical condition, volatile fatty acid formation and extinction, and dehalogenation after injecting chitin as a contaminant treatment additive according to the present invention, respectively.

11 is a graph showing a dechlorination process after injecting ferrous iron as a contaminant treatment additive according to the present invention.

Claims (5)

One or more of sand propagants and guar gum and water mixtures and solid carbon or nutrient materials, abiotic treatment agents, abiotic and biological combination treatment agents and high viscosity or semisolid treatment agents using underground soil crushers By spraying the liquid slurry containing the selected remediation amendments to the underground soil by pumping it at a higher pressure than the ground pressure, the contaminant treatment additive is injected into the expanded pores and the soil at the same time as the pores are expanded in the underground soil. Delivering widely within; Measuring the surface slope of the soil changed by the liquid slurry injected into the underground soil with a plurality of geophysical tiltmeters installed on the ground surface, and databaseting the measured tilt information; And A method of purifying soil and determining the state of soil, comprising the step of drawing the location of the pollutant treatment additive distributed in the underground soil in a three-dimensional image by using the database-based gradient information. delete The method of claim 1, wherein after the drawing step, And measuring the surface slope of the soil that is changed by purifying the contaminants in the underground soil by the contaminant treatment additive, and monitoring the pollution purification state using the measured slope information. How to check for cleanup and contamination. The method of claim 1, wherein after the drawing step, Re-spraying the liquid slurry to the underground soil, measuring the surface slope by the re-injection, and plotting the location of the contaminant treatment additive using the measured slope information; Soil characterized in that it further comprises To clean and contaminate the environment. The groundwater pipe of claim 1, wherein the contaminant treatment additive is selected from at least one selected from solid carbon or nutrient materials, abiotic treatment agents, abiotic and biological treatment agents, and high viscosity or semisolid treatment agents. Soil purification and contamination check method of the soil, characterized in that further comprising the step of delivering to the generated voids through

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