KR101952610B1 - IOT based contamination area fate modeling system by real time monitoring of in-situ contaminated soil purification well - Google Patents

Abstract

The present invention relates to an IoT-based soil contamination area diffusion and behavior modeling system by real-time monitoring of a contaminated soil underground purification well and, more specifically, to an IoT-based soil contamination area diffusion and behavior modeling system by real-time monitoring of a contaminated soil underground purification well which monitors an underground purification well in real time based on collected sensor data from the underground purification well in a process of purifying contaminated soil underground, thereby creating a pollution modeling map or effectively purifying the contaminated soil. The IoT-based soil contamination area diffusion and behavior modeling system by real-time monitoring of a contaminated soil underground purification well comprises a sensor unit, a server unit and a web dashboard unit.

Description

TECHNICAL FIELD [0001] The present invention relates to an IOT-based contaminated soil modeling system,

The present invention relates to a system for modeling the behavior of a soil contaminated area by real-time monitoring of contaminated soil underground, and more particularly, The present invention relates to a soil modeling system for soil contamination by real-time monitoring of soil contaminated soil in order to efficiently clean contaminated soil,

Generally, techniques for purifying contaminated soil can be classified into biological methods and physicochemical methods.

The physico-chemical method is a method of purifying by using the physical and chemical properties of the pollutants. There are methods such as soil washing, incineration, solidification, stabilization and solvent extraction. There is a drawback that it can cause contamination.

The biological method is a method of decomposing and removing the oil using a microorganism that is a petroleum-based hydrocarbon decomposing strain, and there are methods such as soil cultivation, composting, bioventing, and plant restoration. It is cheaper than physicochemical methods and does not cause secondary environmental pollution, but takes a long time to restore contaminated soil.

The soil remediation technology classified by the physicochemical method and the biological method as described above can be classified into the ground treatment method (Ex-situ method) and the ground treatment method (In-situ method) according to the method to which the technique is applied.

The soil treatment method (Ex-situ method) is to grasp the distribution of pollutants in the soil and the physical / chemical characteristics of the soil, excavate the contaminated soil to the extent to be treated, , Which is also referred to as an excavation treatment method, includes a general soil washing.

The in-situ method is a technique to inject the chemicals, oxidants, microorganisms, etc. directly from the ground by inserting the gutters into the ground, and it is a technology that injects cleaning solution, cleaning solution discharging solution, washing effluent treatment facility, Material treatment facilities are installed on the contaminated site, and the washing water is injected and circulated in the contaminated soil to be treated.

Among the physical chemical methods, chemical oxidation, soil vapor extraction (SVE), air sparging, soil flushing, and so on can be applied to the in-situ method. Bio-slurping and so on. Among the biological methods, land-cultivation, bioventing, bioreactor, etc. are applicable to the in-situ method. have.

In addition, an underground high-pressure injection method is also widely used in which contaminated soil is purified by injecting a cleaning liquid at a fixed position through an in-situ installation of an in-situ method.

On the other hand, the dissolution and migration of soil pollutants in the environmental medium is very difficult because it is difficult to predict the extent and extent of contamination and the behavior of pollutants because of the invisible and complex underground characteristics of various structures. It is necessary to monitor by monitoring.

In particular, the physical, chemical and biological properties of soils vary widely, so for the prediction of soil contaminant behavior and successful soil remediation, the physical (density, permeability, moisture content, diffusion, Sampling and monitoring to accurately understand the characteristics of the chemical (pH, electrical conductivity, redox potential, cation exchange capacity, organic carbon / nitrogen, organic matter content, etc.), biological (microbial species / community distribution, biomass content, etc.) It is important to carry out purification treatment according to the result.

In addition, the dissolution and migration of pollutants into the environmental medium is very difficult because it is difficult to predict the extent and extent of contamination and the behavior of pollutants because of the ineffectiveness and complexity of various underground structures. It is necessary to monitor by monitoring.

In addition, because it is controlled by various physical, chemical and biological characteristics of soil and groundwater, physical (density, permeability, water content, diffusion, flow rate, etc.) of soil and groundwater environment are predicted for prediction of pollutant behavior and successful soil / groundwater purification. , Sampling, and monitoring to accurately understand the characteristics of the chemical (pH, electrical conductivity, redox potential, cation exchange capacity, organic carbon / nitrogen, organic matter content), biological (microbial species / community distribution, biomass content, It is important to perform purification treatment according to the result.

In order to efficiently perform the purification treatment by sampling and monitoring as described above, it is necessary to accurately diagnose and investigate the degree of soil contamination, and it is necessary to grasp the accurate contamination distribution and prepare a contamination map of the contaminated area.

Korean Patent No. 10-0799602 (Jan. 24, 2008) discloses data on air pollution, water pollution, and soil pollution measured by a sensor installed on a source of each pollutant, An initialization step of extracting a pollutant emission amount per unit time of each pollutant emission source and storing it in a database; An air pollution calculation step of calculating an amount of movement of air pollutants from data on weather, topography, air pollution, water pollution, and soil pollution, and calculating a movement amount of the air pollutant to the surface water; A surface water pollution calculation step of calculating the amount of surface pollutant movement from data on weather, topography, air pollution, water pollution, and soil pollution, and calculating the amount of evaporation evaporating from the surface water and the amount of movement to the soil; Calculate the amount of pollutants to be fed into the groundwater from the data on weather, terrain, air pollution, water pollution and soil pollution, and calculate the amount of pollutants to be transferred from the groundwater to the ocean. Wow; A soil pollution calculation step for calculating the amount of movement of the soil pollutants according to the amount of the air pollutants and the amount of the ground pollutants transferred from the data on the weather, topography, air pollution, water pollution, and soil pollution; A correction step of correcting information on the atmospheric, water quality, and soil contamination input through the air pollution calculation step, the surface water pollution calculation step, the ground water pollution calculation step, and the movement amount information for each emission source calculated in the soil pollution calculation step ; And an output step of outputting the calculated result, wherein the air pollution calculation step, the surface water pollution calculation step, the ground water pollution calculation step, and the soil pollution calculation step are repeatedly performed with the information corrected in the correction step Thereby estimating the diffusion of environmental pollution.

Korean Patent No. 10-0952845 (Apr. 06, 2010) discloses a method of using an underground soil crusher to produce a proppant, a guar gum and water mixture, a solid carbon or nutrient material, A liquid slurry containing remediation amendments selected from at least one of an abiotic and a biological composite treatment agent and a high viscosity or semi-solid treatment agent is pumped at a higher pressure than the underground pressure and injected into the underground soil, Expanding and simultaneously injecting the contaminant treatment additive into the expanded void and delivering the contaminant treatment additive broadly within the soil; Measuring a surface slope of the soil that is changed by the liquid slurry sprayed on the underground soil with a plurality of geophysical tiltmeters installed on the surface of the soil and databaseing the measured slope information; And a step of plotting the position of the pollutant-treating additive distributed in the underground soil into a three-dimensional image using the slope information obtained by the database, is known.

Korean Patent Registration No. 10-1406701 (June 04, 2014) discloses a method for monitoring pollutants, comprising the steps of: Monitoring the contamination concentration of the pollutant by sampling and analyzing the groundwater sample at the observation station; Monitoring the groundwater level by monitoring the observation point; And a pollution source identification step of determining a correlation between the pollution concentration and the groundwater level to determine whether the area where the observation observation is installed is a pollution source area, wherein the groundwater sample is sampled at each time point, Setting a groundwater level at a certain point of time as a reference groundwater level, dividing the contamination concentration at each sampling time by the reference pollution concentration, calculating a contamination concentration ratio Obtaining a groundwater level difference by subtracting the reference groundwater level from the groundwater level at each sampling time, and obtaining a correlation between the contamination concentration ratio and the groundwater level difference, Is known.

In Korean Patent No. 10-1570518 (November 13, 2015), as a method of investigating the buried waste, there is a method of investigating buried wastes as follows: (1) the depth of the site 100 to be surveyed is sampled at a sampling point 120 selected according to the lattice method; Analyzing the star sample; And (2) preparing a three-dimensional map of the pollution degree map 200 for the site to be researched 100 using the result of the analysis, wherein the step (1) Selecting a contamination concern area (110) in a target site (100); (1-2) selecting a sample collection point 120 according to the lattice method and taking a sample in consideration of the selected pollution concern area 110; And (1-3) analyzing the depth samples collected at the selected sample collection point 120. The step (2) further includes analyzing the pollution degree map 200 by two- Dimensional pollution degree map 200 can be created by creating the three-dimensional pollution degree map 200 by arranging the two-dimensional pollution degree map by depth and listing the created two-dimensional pollution degree map by using the interpolation method, (2-1) The contamination range 210 is calculated through the soil pollution modeling on the area including the sample collection point 120 exceeding the predetermined standard as a result of the analysis. ; And (2-2) visualizing the calculated contamination range 210 for each contamination depth, thereby creating a three-dimensional map of the distribution state of the contamination range 210. In step (2-1) Dimensional grid within the site to be researched 100 to perform the soil pollution degree modeling. After the step (2), using the pollution degree map 200 created by the three-dimensional map, Wherein the method further comprises the step of deriving a method for estimating buried wastes using a three-dimensional map.

However, the above-mentioned conventional techniques are a method of confirming contamination purification and contamination of the soil by using the slope of the soil surface which is changed by the liquid slurry injected into the soil pores by injecting the pollutant treatment additive into the soil soil, A method of visualizing the calculated range of contamination by the depth of contamination, and a method of creating a three-dimensional map of the distribution of the range of contamination. In the present invention, in the process of underground purification of contaminated soil, Based on the sensor data, it is possible to monitor the groundwater remediation system in real time and create a contamination modeling map based on it. In order to efficiently purify the contaminated soil, IOT - based soil contamination modeling system based on real - I could not present it.

Accordingly, the present inventors have found that, in the process of purifying a contaminated soil, the groundwater purification plant is monitored in real time based on the sensor data collected in the ground purification plant, and a contamination modeling map is created based on the monitoring data. We have developed a soil modeling system for soil contaminated area by real - time monitoring of IOT - based contaminated soil in - situ.

[Patent Document 001] Korean Patent Registration No. 10-0799602 (Jan. 24, 2008) [Patent Document 002] Korean Patent Registration No. 10-0952845 (April 06, 2010) [Patent Document 003] Korean Patent Registration No. 10-1406701 (June 04, 2014) [Patent Document 004] Korean Patent Registration No. 10-1570518 (November 13, 2015)

In order to solve the above problems, in order to solve the above-mentioned problems, in the process of purifying contaminated soil, it is necessary to monitor the underground purifier in real time based on the sensor data collected in the purifier tank, The present invention provides a soil pollution modeling system for soil contamination by real-time monitoring of contaminated soil in-ground purification facilities for purification of IOT-based soil.

In order to solve the above problems, the present invention provides a pollution level sensor, a pH sensor, a temperature sensor, a water level sensor, a water level sensor, and a rainfall sensor for measuring the degree of pollution of pollutants connected to a plurality of excavated wells A server unit for collecting each sensor data transmitted from the sensor unit by sensor data type; and a server unit for receiving sensor data desired by the user from the server unit in real time Wherein the web dashboard unit comprises a web dashboard unit for displaying the behavior distribution history screen and the distribution comparison screen for each sensor data type of the contaminated area, Modeling System of Soil Contaminated Area by Real-Time Monitoring And the means to solve the problem.

The contaminated soil underground purification may be carried out by purifying the extracted soil by purging the extracted water by injecting at least one selected from the cleaning chemicals including water, soil cleaner and chemical oxidizer into the plurality of tanks, And the soil vapor is purified by the purification apparatus.

The pollutants include petroleum based products including benzene, toluene, xylene, ethylbenzene, petroleum hydrocarbon (TPH), trichlorethylene (TCE), tetrachlorethylene (PCE), organic phosphorus compounds, benzopyrene, PCB, Contaminants; And heavy metal contaminants including arsenic, lead, cadmium, hexavalent chrome, copper, mercury, zinc, nickel, and fluorine.

The contamination level sensor may include a gas chromatograph (GC), a gas chromatography-mass spectrometer (GC-MS), an atomic absorption spectrophotometer, an atomic emission photometer, a spectrophotometer, an infrared spectrophotometer, And selecting and using an analyzing device constituted as a solution to the problem.

The pollution degree sensor is a means for solving the problem of measuring the pollution degree by using a soil steam extraction or a pollutant extract liquid in which a polluted soil sampled is washed with water and / or a solvent.

The distribution history screen shows the contaminated area map including the contamination area range, the depth of contamination, the sensor data value for each of the plurality of sites, and the two-dimensional or three-dimensional contour map of the sensor data based on the data, A sensor data type selection window for selecting the sensor data type on the contamination map screen, and a slide bar for selecting the start and end date, so that the contamination area range of the sensor data selected during the selection period, the contamination depth, Dimensional data or three-dimensional contour data of the sensor data based on the sensor data values and the sensor data values.

The distribution comparison screen constitutes a sensor data type selection window for selecting a sensor data type, and based on the selected sensor data type, a contaminated area map, a contamination depth map, sensor data values for a plurality of locations, And a change history including a two-dimensional or three-dimensional contour diagram of the sensor data is divided and displayed in a period-by-period comparison screen.

The two-dimensional or three-dimensional contour map for each sensor data type represents the numerical range by the respective colors.

The soil contamination zone behavior modeling system by real-time monitoring of the IOT-based contaminated soil underground groundwater purification facility can be confirmed or controlled by online connection to the purification treatment construction company or supervisory authority.

The IOT-based soil contamination soil remediation system of the present invention is realized by real-time monitoring of the soil contamination site behavior modeling system in real time monitoring the groundwater remediation system based on the sensor data collected in the soil remediation process during the soil remediation of the contaminated soil, It is possible to monitor the pollution degree in real time and model the behavior of the polluted area without needing to investigate the pollution degree separately. Therefore, it is possible to reduce manpower, time and cost required for the pollution survey.

1 is a schematic diagram showing the overall configuration of a modeling system for soil contamination zone by real-time monitoring of an IOT-based contaminated soil underground purification plant of the present invention
FIG. 2 is a view showing the distribution history of the web dashboard unit of the soil-contaminated site modeling system by real-time monitoring of the IOT-based contaminated soil underground purification plant of the present invention
FIG. 3 is a view showing the distribution history of the web dashboard unit of the soil-contaminated region modeling system of the soil contamination zone by real-time monitoring of the IOT-based contaminated soil underground purification plant of the present invention
4 is a view showing the distribution history of the web dashboard unit of the modeling system of the soil contaminated area by real-time monitoring of the IOT-based contaminated soil underground purification plant of the present invention
FIG. 5 is a graph showing the distribution of soil dirt area modeling system web dashboard unit by the real-time monitoring of the IOT-based contaminated soil in situ

In order to solve the above problems, the present invention provides a pollution level sensor, a pH sensor, a temperature sensor, a water level sensor, a water level sensor, and a rainfall sensor for measuring the degree of pollution of pollutants connected to a plurality of excavated wells A server unit for collecting each sensor data transmitted from the sensor unit by sensor data type; and a server unit for receiving sensor data desired by the user from the server unit in real time Wherein the web dashboard unit comprises a web dashboard unit for displaying the behavior distribution history screen and the distribution comparison screen for each sensor data type of the contaminated area, Modeling System of Soil Contaminated Area by Real-Time Monitoring And the feature of the technology configuration.

The contaminated soil underground purification may be carried out by purifying the extracted soil by purging the extracted water by injecting at least one selected from the cleaning chemicals including water, soil cleaner and chemical oxidizer into the plurality of tanks, And the soil vapor is purified by the purification apparatus.

The pollutants include petroleum based products including benzene, toluene, xylene, ethylbenzene, petroleum hydrocarbon (TPH), trichlorethylene (TCE), tetrachlorethylene (PCE), organic phosphorus compounds, benzopyrene, PCB, Contaminants; And heavy metal contaminants including arsenic, lead, cadmium, hexavalent chromium, copper, mercury, zinc, nickel, and fluorine.

The contamination level sensor may include a gas chromatograph (GC), a gas chromatography-mass spectrometer (GC-MS), an atomic absorption spectrophotometer, an atomic emission photometer, a spectrophotometer, an infrared spectrophotometer, And selecting and using an analyzing apparatus constituted by the analyzing apparatus.

The pollution degree sensor is characterized in that the degree of pollution is measured using a soil steam extraction or a pollutant extract liquid in which contaminated soil sampled is washed with water and / or a solvent.

The distribution history screen shows the contaminated area map including the contamination area range, the depth of contamination, the sensor data value for each of the plurality of sites, and the two-dimensional or three-dimensional contour map of the sensor data based on the data, A sensor data type selection window for selecting the sensor data type on the contamination map screen, and a slide bar for selecting the start and end date, so that the contamination area range of the sensor data selected during the selection period, the contamination depth, And the sensor is configured to show a change history including a sensor data value and a two-dimensional or three-dimensional contour map of the sensor data based on the sensor data value.

The distribution comparison screen constitutes a sensor data type selection window for selecting a sensor data type, and based on the selected sensor data type, a contaminated area map, a contamination depth map, sensor data values for a plurality of locations, And a change history including two-dimensional or three-dimensional contour maps of the sensor data is divided and displayed in a period-by-period comparison screen.

The two-dimensional or three-dimensional contour map of each sensor data type is characterized by indicating the numerical range by each color.

The soil contamination area behavior modeling system by the real-time monitoring of the IOT-based contaminated soil underground purification plant can be confirmed or controlled by on-line access to the purification construction contractor or supervisory authority.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. The present invention may, however, be embodied in many different forms and should not be construed as limited to the illustrative embodiments set forth herein.

Referring to FIG. 1, the soil-contaminated area modeling system based on the real-time monitoring of the IOT-based contaminated soil in-situ monitoring system of the present invention comprises a pollutant- A sensor unit including a pollution degree sensor for measuring pollution degree, a pH sensor, a temperature sensor, a water level sensor, a pumped water amount sensor and a rainfall amount sensor, and a server for collecting sensor data transmitted from the sensor unit, And a web dashboard unit for displaying the sensor data desired by the user from the server unit so that the sensor data can be checked or controlled in real time according to the site and sensor data type, It is composed of a behavior history distribution screen for each data type and a distribution comparison screen .

At this time, in the contaminated soil underground purification, at least one selected from the cleaning chemicals including water, soil cleaner and chemical oxidizer is injected into the plurality of wells and the extracted water is pumped and purified by the purifier or the plural The soil vapors can be extracted from the wells of the plant and purified by the purification apparatus.

In addition, the contaminants may be selected from the group consisting of benzene, toluene, xylene, ethylbenzene, petroleum hydrocarbon (TPH), trichlorethylene (TCE), tetrachlorethylene (PCE), organophosphorus compounds, Petroleum-based pollutants; Heavy metal contaminants including arsenic, lead, cadmium, hexavalent chromium, copper, mercury, zinc, nickel, and fluorine.

Particularly, the pollution level sensor may be classified into a gas chromatograph (GC), a gas chromatography-mass spectrometer (GC-MS), an atomic absorption spectrophotometer, an atomic emission photometer, a spectrophotometer, an infrared spectrophotometer, And selecting and using an analyzing device including the analyzing device.

At this time, the pollution degree sensor can measure pollution degree by using soil steam extraction or polluted substance extract obtained by washing contaminated soil sampled with water and / or solvent

As shown in FIG. 2 to FIG. 4, the distribution history screen displays a map of a contaminated area, a range of contamination areas, a depth of contamination, sensor data values for a plurality of areas, A sensor data type selection window for selecting a sensor data type on a contamination map screen including a three-dimensional contour map, a purifier position, and a well-being position, a period slide bar for selecting start and end dates, The contamination depth range of the selected sensor data, the depth of contamination, the sensor data value for each of the plurality of observations, and the two- or three-dimensional contour map of the sensor data based on the sensor data.

That is, when the sensor data type is selected on the distribution history screen and the slide bar is slid from the beginning to the end, the range of the contaminated area from the start to the end date, the depth of contamination, the sensor data type, The change histories of the two- or three-dimensional contour maps according to the data types can be displayed, and the state of contamination reduction during the purging period can be confirmed.

As shown in FIG. 5, the distribution comparison screen configures a sensor data type selection window for selecting a sensor data type and displays a contaminated area map, a contamination depth map, a plurality of And a change histogram including a two-dimensional or three-dimensional contour map of the sensor data based on the sensor data value and the change history of the sensor data on the basis of the sensor data. .

In addition, the two-dimensional or three-dimensional contour map for each type of sensor data can represent the numerical range by each color.

In addition, the soil contamination area behavior modeling system by the real-time monitoring of the IOT-based contaminated soil underground purification plant can be confirmed or controlled by on-line access to the purification construction contractor or the supervisory authority.

The foregoing description is merely illustrative of the technical idea of the present invention, and various changes and modifications may be made by those skilled in the art without departing from the essential characteristics of the present invention. Therefore, the drawings disclosed in the present invention are not intended to limit the scope of the present invention and are not intended to limit the scope of the present invention. The scope of protection of the present invention should be construed according to the following claims, and all technical ideas within the scope of equivalents should be construed as falling within the scope of the present invention.

Claims (9)

A sensor unit including a pollution degree sensor, a pH sensor, a temperature sensor, a water level sensor, a pumped water amount sensor, and a rainfall amount sensor for measuring the pollution degree of pollutants connected to a plurality of excavated wells for polluted soil underground purification, A server unit for collecting the sensor data transmitted from the server unit according to the type of the sensor data; and a web dash for displaying the sensor data desired by the user, And a board unit,
The web dashboard unit includes a behavior distribution history screen and a distribution comparison screen for each sensor data type of the contaminated area,
The contaminated soil underground purification is carried out by purifying the extracted soil by injecting at least one selected from the purification chemicals including water, soil cleaner and chemical oxidizer into the plurality of tanks and purging the extracted water by the purification device, The soil steam is extracted from the soil and purified by the purification apparatus,
The pollutants include petroleum based products including benzene, toluene, xylene, ethylbenzene, petroleum hydrocarbon (TPH), trichlorethylene (TCE), tetrachlorethylene (PCE), organic phosphorus compounds, benzopyrene, PCB, Contaminants; Heavy metal contaminants including arsenic, lead, cadmium, hexavalent chromium, copper, mercury, zinc, nickel, fluorine,
The pollution degree sensor measures pollution degree by using a soil steam extraction or a pollutant extract obtained by washing a polluted soil sampled with water or a solvent. The pollution degree is measured by gas chromatography (GC), gas chromatography- An analytical apparatus including a mass spectrometer (GC-MS), an atomic absorption spectrophotometer, an atomic emission photometer, a spectrophotometer, an infrared spectrophotometer, and an ultraviolet spectrophotometer is selected and used
The distribution history screen shows the contaminated area map including the contamination area range, the depth of contamination, the sensor data value for each of the plurality of sites, and the two-dimensional or three-dimensional contour map of the sensor data based on the data, A sensor data type selection window for selecting the sensor data type on the contamination map screen and a period slide bar for selecting the start and end date are provided so that the contamination area range of the sensor data selected during the selection period, Wherein the sensor data is configured to show a change history including a sensor data value and a two-dimensional or three-dimensional contour map of the sensor data based on the sensor data value,
The distribution comparison screen constitutes a sensor data type selection window for selecting a sensor data type, and based on the selected sensor data type, a contaminated area map, a contamination depth map, sensor data values for a plurality of locations, Wherein the change history includes a two-dimensional or three-dimensional contour map of the sensor data in a periodic comparison screen.
delete delete delete delete delete delete The method according to claim 1,
Wherein the two-dimensional or three-dimensional contour map of each sensor data type represents the numerical range by each color, and the IOT-based soil contamination soil modeling system
The method according to claim 1,
The soil-contaminated area behavior modeling system by the real-time monitoring of the IOT-based contaminated soil underground groundwater purification facility can be confirmed or controlled by on-line access to the purification construction contractor or supervisory authority, Monitoring Modeling System for Soil Contamination Behavior

Images