KR101952607B1 - IOT based contamination area fate modeling system by real time monitoring of contaminated groundwater well - Google Patents

Abstract

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

Description

[0002] IOT-based contamination modeling system based on real-time monitoring of contaminated groundwater based on IOT [

The present invention relates to a system for modeling a contaminated area based on real-time monitoring of contaminated groundwater based on IOT, and more particularly, , And to a contaminated area modeling system by real-time monitoring of contaminated groundwater based on IOT for efficiently purifying contaminated groundwater.

In general, ground water is water that reaches a layer that does not penetrate water because part of the rainfall penetrates into the clearance of the soil from the surface of the ground. Water is also present in the upper part of the underground water surface. When the gap is small, The groundwater in the contaminated soil must be treated in the same time as the groundwater can be seriously degraded by the nearby military units, gas stations or factories within a short period of time. As a treatment method, there is developed a method of excavating contaminated soil, treating contaminated ground water by pumping water, or extracting pollutants after setting injection and extraction tablets in situ, and purifying microorganisms and nutrients by injecting chemical treatment agents, etc. Widely used

In this case, the amount of the cleaning agent should be automatically adjusted according to the concentration of the pollutant during the purification process, and the cleaning agent must be supplied along the direction of the pollutant movement according to the groundwater flow.

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.

As a conventional technique developed for this purpose, Korean Patent No. 10-0978939 (Aug. 24, 2010) pumped deep-sea groundwater or excavated groundwater contaminated with various pollutants such as organic pollutants and heavy metals, A siltous water separation tank for separating sand and / or inorganic impurities having a large specific gravity contained in the silt and the at least one oil selected from the group consisting of light oil, kerosene and total petroleum hydrocarbon (TPH) , A water collecting tank for temporarily storing the inflowed contaminated ground water while maintaining the water at a predetermined water level, and a water supply unit for supplying the contaminated water from the contaminated ground water, which is composed of Al, Fe, Cr, Cd, Cu, Pb, Hg, As, (CN), n-hexane extract material, suspended solids (SS) or a precipitate, together with the chemicals supplied from the chemical reservoir, A chemical reaction slag plate settling tank for chemical reaction, neutralization and flocculation to precipitate and remove fine precipitates from the slope plate of the slope plate settling section, and a micro-fine sloping plate settler disposed in the contaminated groundwater flowing from the chemical reaction slash plate settling tank, (BTH), benzene, toluene, ethylbenzene, and xylene, which diffuse into the floating separation portion of the flotation separation and diesel soot, and are selected from the group consisting of light oil, kerosene and total petroleum hydrocarbons Volatile organic compounds (VOCs) selected from the group consisting of phenol, trichlorethylene (TCE), perchlorethylene (PCE), finely suspended solids (SS) The Hexane extract was flashed off, and the strips were packed with polypropylene packings. The stripper was composed of a stripper and a demister. A floatation dewatering tank for degassing the VOCs and then adsorbing the activated carbon tower to the activated carbon, and an ozone (O3) injecting device for treating the groundwater introduced from the floatation dewatering tank to the level of domestic water (S) and / or BTEX (benzene, toluene, ethylbenzene, xylene) selected from the group consisting of n-hexane extracts, diesel oil, kerosene and total petroleum hydrocarbons At least one volatile organic compound material (VOCs) selected from the group consisting of phenol, trichlorethylene (TCE), perchlorethylene (PCE) And an advanced oxidation treatment tank capable of re-injecting or discharging the groundwater again after purification by oxidation treatment, chromaticity removal, and deodorization by an Advanced Oxidation Process (hereinafter referred to as " Advanced Oxidation Process "); A controller installed in at least one of the sedimentation water collecting tank, the chemical reaction slope plate settling tank, the floating separation deaeration tank, and the advanced oxidation treatment tank of the complex contaminated groundwater purification apparatus, and is connected to the surveillance camera and water quality measuring apparatus, A remote terminal device for transmitting data to the system or receiving a control command of the centralized control remote monitoring control system to perform real time control; A wired / wireless network connected to a data communication unit of the remote terminal apparatus and performing data communication; A field interface unit (FIU) connected to the wired / wireless network for relaying data communication between the remote terminal device and the central control remote monitoring and control system; And a remote control interface configured to notify an administrator of the information of the complex contaminated groundwater purification apparatus or to input information from an administrator. Lt; / RTI >

Korean Patent Registration No. 10-1248848 (Mar. 25, 2013) discloses a real-time monitoring system for soil and groundwater environment, which is installed on at least one observation site to measure the state of the soil and groundwater on the observation site, A status monitoring unit connected to the status measurement sensor unit for monitoring status information, and a remote monitoring unit for receiving status information monitored through the monitoring unit monitoring unit and providing the monitored status information through a user interface (UI) And a remote monitoring server, the remote monitoring server including at least one portable terminal for receiving a message registered in the remote monitoring server, wherein the remote monitoring server includes a status monitoring unit for receiving and storing status information generated in the status measuring sensor unit in real time, A status information collecting unit for transmitting the status information to the remote monitoring server; An observation site information storage unit for storing surrounding information of the observation site; An information providing unit for providing the status information and the peripheral information; An operation mode control unit for controlling the status information collection unit and the information storage unit to selectively provide the status information or the peripheral information to the information providing unit in accordance with the administrator mode or the user mode; And a power supply unit for supplying power to the status measurement sensor unit and the monitoring unit monitoring unit, wherein the status information collection unit comprises: a status information storage module for storing status information received by the status measurement sensor unit; A communication module for wirelessly transmitting status information stored in the status information storage module to the remote monitoring server; A control module controlling the state measuring sensor to operate according to a set input value including one of time, temperature, and rainfall to minimize power consumption by turning on / off the power of the state measuring sensor; And a status information comparison module for comparing the status information generated by the status measurement sensor unit with predetermined status information, wherein the status information comparison module is configured to compare status information generated by the status measurement sensor unit with predetermined status information An alarm is transmitted to the remote monitoring server through the communication module or status information generated by comparing the generated status information with a predetermined plurality of user-specific status information, The operation mode control unit transmits the alert message to the corresponding portable terminal of the previously registered portable terminal by transmitting an alarm for each user to the remote monitoring server, Mode, the status information and the surrounding information The state information collecting unit and the observation site information storing unit are configured to be capable of editing state information and surrounding information respectively stored in the state information collecting unit and the observation site information storing unit through the information providing unit when the observing site monitoring unit is operated in the administrator mode A real-time monitoring system of soil and groundwater environment is known.

Korean Patent Registration No. 10-1451385 (Oct. 08, 2014) discloses a soil sampling apparatus for sampling and analyzing a test substance contained in soil or ground water. The soil sampling apparatus includes an internal space containing a sorbable material capable of adsorbing the test substance And an adsorption module formed to allow the soil or groundwater to flow from the outside into the inner space, wherein the adsorption module is detachably coupled to the inner space, and the inner space Wherein the plurality of adsorption cells are vertically spaced apart from each other by a predetermined distance, the method comprising the steps of: The soil core was stored in a soil core lining tube to preserve the soil core intact, and then the soil core Storing the soil at a temperature of 5 to < RTI ID = 0.0 > 5 C < / RTI > A soil core removing step of removing the outer surface of the chilled soil core to a predetermined thickness in the anaerobic chamber and obtaining the inner contents of the soil core; And a number of the adsorption cells is determined according to a necessary number of analysis times to form the adsorption module; A sorbent material inserting step of inserting a sorbent material into each internal space of the adsorption cell; An adsorption module dropping step of dropping the adsorption module including the adsorbent to a predetermined depth in the borehole; Culturing the adsorption module in the borehole for a predetermined period of time; An adsorbent recovery step of recovering the adsorbent contained in at least one of the plurality of adsorption cells after recovering the adsorption module from the borehole; An adsorbent analyzing step of analyzing the adsorbent separated from the adsorbed cells recovered from the borehole; A method for monitoring the soil groundwater purification is disclosed.

Korean Patent No. 10-1792808 (Oct. 26, 2017) discloses an extraction step (S100) for extracting ground water from the ground; A separation step (S200) of separating the extracted ground water from the liquid and the gas phase through the gas-liquid separator; A monitoring step (S300) of monitoring the number of extracted extracts; An information transmitting step (S400) of sending the monitored information to the control unit; Analyzing the transmitted information (S500); A cleaning agent input step (S600) for inputting a cleaning agent according to the analyzed information; An extracted groundwater treatment step (S700) for purifying the extracted groundwater after the monitoring analysis is completed; A cleaning agent recovery step (S800) for recovering nanosphere iron oxide through magnetic force sorting in treated groundwater; A discharging step (S900) of discharging the purified groundwater; (S1000), wherein the monitoring step (S300) includes monitoring of TPH, TVOCs, BTEX, TCE, PCE, and nitrate / ammonium monitoring Characterized in that it comprises; In the step of injecting the cleaning agent (S600), the cleaning agent is characterized by selectively injecting nano-spheroidal iron, microorganisms, nutrients, oxidizing agents, catalysts, and surfactants by pollutant and soil characteristics; In the extracted groundwater treatment step (S700), the gas and liquid separated from the gas-liquid separator are monitored through a gas analyzer and a water quality analyzer, respectively, and the gas is collected through an adsorption tower using activated carbon or the like to reduce the contamination concentration, (S600) in the case of a liquid; The nano-zero zero-point withdrawal means (S800) recovers the nano-zero zero iron among the purifying agents injected from the treated groundwater through the extracted groundwater treatment step (S700) through magnetic force sorting. The extracted groundwater in the sampling tank and the extra The groundwater is transferred to the water treatment system, and the water treatment system consists of a nanoreactor and a magnetic separation and recovery device. The groundwater is surface-modified with a cleaning agent CMC-nZVI (carboxylmethyl cellulose), TPO Fe3O4 @ MAA (Methacrylic acid), Fe3O4 @ Al (OH), and Fe3O4 @ Al (OH) are the most commonly used microorganisms, ) 3, Fe3O4 @ SiO2, microorganisms, nutrients, oxidants, catalysts, and surfactants are selectively injected by the pollutant and soil characteristics, reacted with nano- (S100) to (S900) are sorted by sheet to be managed and transferred to a chemical tank in an automatic cleaning agent remover system, and then recycled. (S600) in which a cleaning agent is input in accordance with the analyzed information, and a control PC with a built-in PLC program is used in the cleaning step (S300) It is possible to receive data on the site and control the injection of the purifying agent, and to remotely receive and control the smartphone even if the user does not go directly to the site.

Korean Patent Registration No. 10-1728134 (Apr. 12, 2017) discloses an observation unit installed in a space set within a tunnel to monitor the groundwater condition in the tunnel; A tubular rod providing a passage for connecting the tube and the cable to the observation unit; A pair of packing members enclosing the outer circumferential surface of the rod and supplying air through a tube passing through the rod to expand a volume of the rod to fix the rod to a predetermined position in the tube and to shield an arbitrary space; A fixing bar which fixes the packer to a part of the rod, the connecting bar being provided with a space for installing the observation unit while connecting the pair of packers; And a controller connected to the observation unit and controlling the operation of the observation unit, wherein the packer is made of synthetic rubber and has an outer peripheral surface expanded through air sucking to be fixed in close contact with a predetermined position in the tube, Packer tube; And a pair of packer connectors coupled to upper and lower ends of the packer tube and fixed to the rod through the fixing member by using the fixing member and having a hole through which a tube and a cable are inserted, A tube through hole formed along a longitudinal direction to provide a passage through which the tube and the cable are passed and a conical shape forming a layer toward the thread in the remaining portion of the thread, A connecting joint comprising a connecting portion which is enveloped and joined by the packer tube; A cylindrical tapered sleeve which is engaged with a part of the outer circumferential surface of the connection joint and is brought into close contact with the connection joint by pressing by advancing; A joint nut which is coupled to the thread of the connection joint and closely contacts the tapered sleeve to the connection portion to fix the packer tube in the tapered sleeve; And a connector o-ring installed at a part of the connection part to provide watertightness by tightly contacting the connection joint when the connection part is coupled with the packer tube.

However, the above-mentioned prior art techniques are used to monitor the soil and groundwater environment in real time before the contaminated groundwater is purified, to monitor the groundwater condition in the groundwater, or to monitor soil groundwater purification during the purification process or to purify contaminated groundwater In the process of purifying the contaminated ground water existing in the basement, as in the present invention, it is only related to the remote control. It is based on the sensor data collected in the city, The modeling system of the contaminated area by the real - time monitoring of the contaminated groundwater based on the IOT is not shown.

Accordingly, the inventors of the present invention have found that, in the course of the contaminated groundwater purification process, the contamination modeling map is generated on the basis of the sensor data collected on the basis of the sensor data collected at the site, and the IOT- We have developed a modeling system for pollution zone behavior by real-time monitoring and completed the present invention.

[Patent Document 001] Korean Patent Registration No. 10-0978939 (Aug. 24, 2010) [Patent Document 002] Korean Patent Registration No. 10-1248848 (Mar. 25, 2013) [Patent Document 003] Korean Patent No. 10-1451385 (October 08, 2014) [Patent Document 004] Korean Patent Registration No. 10-1792808 (October 26, 2017) [Patent Document 005] Korean Patent Registration No. 10-1728134 (April 12, 2017)

In order to solve the above-mentioned problems, the present invention proposes a method of monitoring contaminated groundwater on the basis of sensor data collected in the city during the contaminated groundwater purification process existing in the ground, And to provide a modeling system for pollution zone behavior by real-time monitoring of contaminated groundwater based on IOT.

In order to solve the above-described 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 wells, A server unit for collecting sensor data sent from the sensor unit according to sensor data types; and a server unit for real-time checking the sensor data desired by the user by sensor type and sensor type 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, Of the Pollution Zone Modeling System As a result.

Wherein the contaminated groundwater is purged by purging the contaminated ground water from the plurality of purgings and purging the purged groundwater with the purging device or purging the contaminated groundwater mixed with the purging agent by injecting the purging agent into the plurality of purgings and purifying the contaminated groundwater by the purging device. .

The contaminants are selected from the group consisting of benzene, toluene, xylene, ethylbenzene, petroleum hydrocarbon (TPH), trichlorethylene (TCE), tetrachlorethylene (PCE), organic phosphorus compounds, and; 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 the contaminated ground water sampled in the well.

The distribution history screen includes a contaminated area map including a contaminated area range, a contamination depth, a sensor data value for each of a plurality of sites, and a two-dimensional or three-dimensional map of the sensor data, A sensor data type selection window for selecting a sensor data type on a contamination map screen representing a pollution map screen, and a period slide bar for selecting a start time and an end time date to constitute a pollution area range, a contamination depth, And a change history including a sensor data value and a two-dimensional or three-dimensional equalization degree 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 the change history including the two-dimensional or three-dimensional equi-degree hypothetical diagram of the sensor data is divided and displayed in a period-by-period comparison screen.

The two-dimensional or three-dimensional equi-level hypotenuse for each sensor data type represents the numerical range for each color and represents the solution of the problem.

The contaminated area behavior modeling system by real-time monitoring of the IOT-based contaminated ground water well can be confirmed or controlled by on-line access to the cleanup processing construction company or supervisory authority.

The IOT-based contaminated groundwater modeling system by real-time monitoring of the IOT-based contaminated groundwater wells in accordance with the present invention monitors the groundwater contamination level in real time based on the sensor data collected in the groundwater during the contaminated groundwater purification process in the ground It is possible to monitor the pollution level in real time and model the behavior of the polluted area without needing to do so, thereby saving manpower, time and cost required for investigating the pollution degree.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a schematic diagram showing the overall configuration of a contaminated site behavior modeling system by real-time monitoring of contaminated groundwater in IOT based on the present invention
Figure 2 shows the distribution history screen of the web dashboard unit of the contaminated site behavior modeling system by real-time monitoring of the IOT-based contaminated ground water well of the present invention
FIG. 3 is a view showing the distribution history screen of the web dashboard unit of the contaminated site behavior modeling system by real-time monitoring of the IOT-
Figure 4 shows the distribution history screen of the web dashboard unit of the contaminated site behavior modeling system by real-time monitoring of the contaminated ground water well based on the IOT of the present invention
FIG. 5 is a graph showing a distribution comparison screen of a web dashboard unit based on the contaminated area behavior modeling system by real-time monitoring of the contaminated groundwater in the IOT based on the present invention

The present invention relates to a sensor unit including a pollution degree 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 wells formed for excavation for contaminated groundwater, A server unit for collecting each sensor data transmitted from the sensor unit according to sensor data types; a web server for displaying the sensor data desired by the user from the server unit so that the sensor data can be checked in real- Dashboard unit, wherein the web dashboard unit comprises a contaminant zone behavior modeling system by real-time monitoring of contaminated groundwater contamination based on IOT, which comprises a behavior distribution history screen and a distribution comparison screen for each sensor data type of the contaminated area It is a feature of technology construction.

Wherein the contaminated groundwater is purged by purging the polluted groundwater from the plurality of purgings and purged by a purging device or by purging the contaminated groundwater mixed with the purging agent by injecting the purging agent into the plurality of purgings and purifying the purged groundwater by the purging device. .

The contaminants are selected from the group consisting of benzene, toluene, xylene, ethylbenzene, petroleum hydrocarbon (TPH), trichlorethylene (TCE), tetrachlorethylene (PCE), organic phosphorus compounds, and; 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 level sensor is characterized in that the pollution degree is measured using contaminated ground water sampled in a well.

The distribution history screen includes a contaminated area map including a contaminated area range, a contamination depth, a sensor data value for each of a plurality of sites, and a two-dimensional or three-dimensional map of the sensor data, A sensor data type selection window for selecting a sensor data type on a contamination map screen representing a pollution map screen, and a period slide bar for selecting a start time and an end time date to constitute a pollution area range, a contamination depth, And a change history including a sensor data value and a two-dimensional or three-dimensional equi-degree hypothesis diagram 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 the change histories including the two-dimensional or three-dimensional equi-degree hypothetical diagram of the sensor data are divided and displayed in a period-by-period comparison screen.

The two-dimensional or three-dimensional equidistant hypotenuse of each sensor data type is characterized by showing the numerical range by each color.

The contaminated area behavior modeling system by real-time monitoring of the IOT-based contaminated ground water well can be confirmed or controlled by on-line access to the cleanup processing construction company 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 contaminated area modeling system based on real-time monitoring of contaminated groundwater based on the IOT according to the present invention measures pollution degree of pollutants connected to a plurality of excavated wells for purifying contaminated groundwater. A server unit for collecting the respective sensor data transmitted from the sensor unit according to sensor data types; a server unit for collecting the sensor data for each type of sensor data; a sensor unit including a pollution degree sensor, a pH sensor, a temperature sensor, a water level sensor, And a web dashboard unit for displaying the sensor data desired by the user from the server unit in a real-time manner or in a controllable manner according to the site and the sensor data type, wherein the web dashboard unit is configured to display the behavior distribution A history screen and a distribution comparison screen.

Herein, the contaminated groundwater is purged by purging the contaminated groundwater from the plurality of purgings and purging the contaminated groundwater by injecting the purging agent into the plurality of purgings by the purging device, and purifying the contaminated groundwater by the purging device.

At this time, the pollutants include petroleum based products including benzene, toluene, xylene, ethylbenzene, petroleum hydrocarbon (TPH), trichlorethylene (TCE), tetrachlorethylene (PCE) Contaminants; Heavy metal contaminants including arsenic, lead, cadmium, hexavalent chromium, copper, mercury, zinc, nickel, and fluorine.

The pollution level sensor may be classified into a gas chromatography (GC), a gas chromatography-mass spectrometer (GC-MS), an atomic absorption spectrophotometer, an atomic emission photometer, a spectrophotometer, an infrared spectrophotometer, And the like.

At this time, the pollution level sensor measures the pollution level using the contaminated groundwater sampled in the tunnel.

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 water level map, a three-dimensional water level chart, a purifier device position, and a well location, and a slide bar for selecting start and end date The contamination depth range of the selected sensor data during the period, the depth of contamination, the sensor data value for each of the plurality of observations, and the two-dimensional or three-dimensional equalization degree histories of the sensor data based thereon.

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, It is possible to show the change histories of the two-dimensional or three-dimensional types of data of the degree of hypocentrism of the data. From this, the state of pollution abatement during the purification 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 history including a two-dimensional or three-dimensional equal-degree hypothesis 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. Can be confirmed.

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

Also, the contaminated area behavior modeling system by real-time monitoring of the IOT-based contaminated ground water well can be confirmed or controlled by on-line access to the cleanup processing construction company or 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 the contaminated groundwater purification, A web dashboard unit for displaying the sensor data desired by the user from the server unit in such a manner that the sensor data can be checked in real time for each site and sensor data type, ≪ / RTI >
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 groundwater is purged by purging the contaminated groundwater from the plurality of purgings, purging the contaminated groundwater by injecting the purging agent into the plurality of purgers, purifying the purged groundwater by the purifier,
The contaminants are selected from the group consisting of benzene, toluene, xylene, ethylbenzene, petroleum hydrocarbon (TPH), trichlorethylene (TCE), tetrachlorethylene (PCE), organic phosphorus compounds, and; Heavy metal contaminants including arsenic, lead, cadmium, hexavalent chromium, copper, mercury, zinc, nickel, fluorine,
The pollution level sensor measures pollution degree by using contaminated groundwater sampled in a city hall. The pollution degree sensor can measure the pollution degree by using gas chromatography (GC), gas chromatography-mass spectrometer (GC-MS), atomic absorption spectrophotometer, A spectrophotometer, a spectrophotometer, an infrared spectrophotometer, and an ultraviolet spectrophotometer,
The distribution history screen includes a contaminated area map including a contaminated area range, a contamination depth, a sensor data value for each of a plurality of sites, and a two-dimensional or three-dimensional map of the sensor data, A sensor data type selection window for selecting a sensor data type on a contamination map screen representing a pollution map screen, and a period slide bar for selecting a start time and an end time date to constitute a pollution area range, a contamination depth, Wherein the sensor data is configured to represent a change history including a sensor data value and a two-dimensional or three-dimensional equalization hypothesis diagram 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 equilibrium hypothetical diagram 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 water level hypothesis diagram for each type of sensor data represents the numerical range by each color, and is characterized in that the IOT-based contaminated groundwater modeling system
The method according to claim 1,
The IOT-based contaminated groundwater modeling system by real-time monitoring of the contaminated groundwater contamination site can be confirmed or controlled by on-line access to the purification contractor or supervisory authority. Behavior Modeling System

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