KR101952611B1 - IOT based real time monitoring and automatic control system of contaminated groundwater purification equipment - Google Patents

Abstract

The present invention relates to a system for monitoring IoT based contamination groundwater purification equipment in real time and automatically controlling the same and, more specifically, to an automatic purification equipment control system by monitoring IoT based contamination groundwater purification equipment in real time which monitors a purification process of purification equipment based on sensor data collected during a process of purifying contamination groundwater so as to automatically purify the purification equipment.

Description

Technical Field [0001] The present invention relates to an IOT-based contaminated groundwater purification apparatus,

The present invention relates to a real-time monitoring and automatic control system for an IOT-based contaminated groundwater purification apparatus, and more particularly, to a system and method for performing a purification process of a purification apparatus based on sensor data collected in the course of purifying contaminated groundwater And more particularly, to an automatic control system for purifying apparatus by real-time monitoring of an IOT-based contaminated groundwater purification apparatus for automatically controlling a purification apparatus based on monitoring in real time.

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.

Accordingly, it is necessary to develop an automatic control system for purifying apparatus that can control the amount of pollutant and the degree of contamination and the amount of water in the purifier by the real-time monitoring of the purifying process.

As a conventional technique related to the automatic control system for purifying apparatuses, there has been proposed a method of controlling a plurality of purifiers installed in the ground of contaminated soil in Korean Patent No. 10-1276538 (Jun. 13, 2013) An air compressor installed outside each of the wells to generate compressed air for injecting air into each of the wells so as to generate microcracks in the ground of the contaminated soil by the pressure of air; An air inlet port including an air blower for sending the air to the duct and a motor for driving the air blower; A chemical liquid tank for containing a chemical liquid to supply a chemical solution for purifying the contaminated soil through fine cracks to the respective wells provided outside the respective wells and a chemical liquid supply pump for supplying the chemical liquid to each of the wells, A device section; A pumping motor installed outside each of the wells for discharging contaminants and contaminated groundwater contained in the contaminated soil to the outside, such as a chemical solution for purifying contaminated soil; And a blower for generating a pumping force to flow contaminated ground water and discharge the contaminated groundwater and contaminated groundwater to the outside, and a pollutant and contaminated groundwater sent from each of the pollutants and contaminated groundwater to the water treatment apparatus, And a sludge tank for containing contaminated ground water; A switch valve box provided between each of the device units and each valve unit and having an opening / closing control valve that opens and closes the air injected into and discharged from each valve unit and the chemical solution and contaminants from the valve unit; A selector valve provided between the switch valve box and each of the ducts for selectively opening and closing a plurality of flow lines for injecting air and chemical liquid into the respective ducts or discharging pollutants in accordance with opening and closing of the opening / A main header having a valve; Closing control valves of the switch valve box to detect the pressure in the respective pipes and to control the injection of air and chemical liquid into the pipes and the discharge of contaminants in the pipes according to the sensed pressure Wherein the monitoring unit includes a digital pressure gauge that receives a signal sensed by a sensor connected to each gauge and continuously measures pressure changes in the gauge at intervals of at least one second, A data collecting unit connected to the digital pressure gauge for receiving and measuring the pressure value measured by the digital pressure gauge, a set value data unit for converting the pressure values of the pressure values set in the respective gauges into data, And the measurement data of the data collecting unit and the setting data of the set value data unit are compared with each other A control unit connected to the comparison unit and controlling each device unit and various configurations according to comparison data compared by the comparison unit; and a display unit connected to the control unit, Wherein the polluted soil is treated by the method of the present invention.

Also, in Korean Patent No. 10-1831387 (Feb. 14, 2018), an extraction pipe for extracting ground water from the bottom of the ground to the upper surface of the ground; A water separation tank for separating and removing the treated free phase oil; Groundwater adjustment tank; An alkaline storage tank connected to the groundwater adjustment tank; An oxidant storage tank connected to the groundwater adjustment tank; Injection wells that inject groundwater from the top of the ground to the bottom of the ground; And a groundwater flow pipe connecting the extraction pipe, the water separation tank, the groundwater adjustment tank, and the injection pipe, wherein the groundwater flows along the groundwater flow pipe along the extraction pipe, the water separation tank, the groundwater adjustment tank, And an alkaline substance is injected from the alkali storage tank into an underground water adjustment tank, and an alkaline substance is injected into the groundwater adjustment tank from the oxidizer storage tank, Is operated to adjust the concentration of the oxidizing agent in the groundwater to 3 to 5 g / L through the process of injecting the oxidizing agent from the oxidizing agent reservoir into the groundwater regulating tank, wherein the concentration of the oxidizing agent in the groundwater is controlled to be in the range of 10.42 to 11.53. Apparatus is known.

Further, Korean Patent Registration No. 10-1778609 (Sep. 08, 2017) discloses a Fenton purifying apparatus for selectively performing Fenton purifying treatment on polluted water; A biological purification device for performing a biological purification treatment of nitrification treatment and denitrification treatment on the contaminated water; A contaminated water extracting and supplying device for extracting the contaminated water and supplying the extracted water to the Fenton purifier or the biological purification device; And an optional distribution device for sequentially supplying the contaminated water to the Fenton purifier and the biological purification device only when the pollutant concentration of the polluted water supplied from the polluted water extracting and supplying device is less than a predetermined concentration, Wherein the selective distribution device comprises: a bypass line extending from the contaminated water extracting and supplying device to branch to the Fenton purifying device and the biological treatment device, the bypass line being arranged to supply the contaminated water; A return line arranged to supply the contaminated water subjected to Fenton purification treatment in the Fenton purification apparatus to the biological treatment apparatus; A measurement unit for measuring a contamination concentration of the contaminated water supplied to the bypass line; First and second valves disposed on the branched bypass line and capable of regulating the quantity of the polluted water supplied to the Fenton purifier and the biological purification apparatus; And a control unit electrically connected to the measuring unit and controlling the first and second valves in accordance with the contamination concentration measured in the measuring unit.

Also, in Korean Patent No. 10-1830288 (Feb. 12, 2018), a digging hole H is formed in the ground so that it is drilled deeper than the groundwater level at all times; A casing casing (100) inserted into the excavation hole (H); A jet pump 200 inserted into the tubular casing 100; An extraction pipe 300 connected to the upper end of the jet pump 200 and extending to the ground; A gas-liquid separator (400) connected to the extraction pipe (300); Pressure water supply means (500) for supplying high-pressure water to the jet pump (200); A water-oil separator 600 connected to the gas-liquid separator 400; And an outlet tank 700 connected to the oil water separator 600. The tubular casing 100 constitutes the upper half and the upper end protrudes from the surface GL and the lower end is always above the groundwater A tubular screen 120 having an upper end coupled to a lower end of the tubular casing main body 110 and a lower end positioned below the groundwater at all times; (110), a tubular cap (140) for closing the upper end of the tubular casing body (110), and a tubular cap The first casing member 160 is inserted between the excavation hole H and the casing casing main body 110 and is inserted between the excavation hole H and the casing casing main body 110 in the vicinity of the lower end of the casing casing main body 110 Surface water, contaminants and air outside the canal are introduced through the excavation hole (H) into the casing casing (100) (120) to introduce oxygen into the casing (100) to remove the volatile organic compounds from the gaseous phase, thereby generating bio-venting. 170 and the lower portion of the second water-siding member 170 and acts as a filter material to prevent the inflow of the water through the sieve screen 120. The first water- The jet pump 200 includes a jet pump main body 210 having upper and lower ends opened and a lower end positioned at a lower portion of the groundwater at all times, A tapered extension pipe 220 connected to the upper end of the jet pump main body 210 and gradually expanding upwardly and a high pressure water pipe 220 extending from the jet pump main body 210 toward the lower end of the expansion pipe 220, A jet nozzle 230 for upward spraying, A high-pressure water supply pipe 240 for supplying high-pressure water to the jets 230, and a high-pressure water supply pipe 240 installed at a lower end of the jet pump main body 210 to supply groundwater, light- And a check valve 250 that allows only the upward flow of the gas and the reverse flow of the downward flow. The extraction pipe 300 is connected to the upper end of the expansion pipe 220, The separator 400 includes a three-phase mixture inlet 410 connected to the extraction pipe 300, a groundwater outlet 420 connected to the high-pressure water supply means 500, a volatile organic And a three-phase mixture conveying unit 440 for conveying the ground water and the light hydrophobic liquid. The high pressure water supply unit 500 is connected to the high pressure water supply pipe 240 And the suction end is connected to the underground feeding of the gas-liquid separator 400 Liquid separator 400 is supplied to the jet nozzle 230 of the jet pump 200 through the high-pressure water supply pipe 240 as high-pressure water and is supplied to the jet nozzle 230 of the jet pump 200. At the same time, And a booster pump (510) for supplying the brine charged in advance to the gas-liquid separator (400) through the high-pressure water supply pipe (240) to the jet nozzle (230) of the jet pump (200) The separator 600 includes an inlet 610 connected to the three-phase mixture conveying part 440 of the gas-liquid separator 400, a light hydrogenated liquid discharging part 620 discharging the separated light hydrophobic liquid, A volatile organic compound discharge unit 630 for discharging the organic compound and a groundwater discharge unit 640 for discharging separated ground water. The discharge tank 700 is connected to the groundwater discharge unit 600 of the oil water separator 600, An inlet 710 connected to the inlet 640, And a discharging unit 720 for discharging the polluted water.

However, the above-mentioned conventional technologies are only related to general purification apparatuses for purifying contaminated ground water in-situ or amniotic fluid purification, and are based on sensor data collected in the process of purifying contaminated ground water existing in the ground, There is no disclosure of an automatic control system for purifying apparatus based on real-time monitoring of the contaminated groundwater purification apparatus based on IOT for automatically controlling the purification apparatus based on the monitoring of the process in real time

Accordingly, the present inventors have found that, in order to control the purification process of the purification apparatus in real time based on the sensor data collected in the process of purifying the contaminated groundwater existing in the ground, and to automatically control the purification apparatus based on this, The present invention has been completed by developing an automatic control system for purifying apparatus by real-time monitoring of the purifying apparatus.

[Patent Document 001] Korea Patent No. 10-1276538 (June 13, 2013) [Patent Document 002] Korean Patent Registration No. 10-1831387 (February 14, 2018) [Patent Document 003] Korean Patent Registration No. 10-1778609 (September 08, 2017) [Patent Document 004] Korean Patent Registration No. 10-1830288 (February 12, 2018)

In order to solve the above problems, the present invention provides a method and apparatus for monitoring a purification process of a purification apparatus on the basis of sensor data collected in a process of purifying contaminated groundwater existing in a basement in real time, And an automatic control system for a purification apparatus by real-time monitoring of an IOT-based contaminated groundwater purification apparatus.

In order to solve the above problems, the present invention provides a pollution level sensor, a pH sensor, and a temperature sensor for measuring the pollution degree of a pollutant connected to each of a plurality of excavated wells and a tool- A sensor unit including a sensor, a water level sensor, a pumped water amount sensor, and a rainfall amount sensor, a server unit for collecting sensor data sent from the sensor unit by sensor data type, Based on the IOT-based contaminated groundwater purification apparatus, which comprises a web dashboard unit for displaying the control data of the IOT-based contaminated groundwater purification apparatus, As a solution.

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 tub or purifier.

The web dashboard unit displays the contaminated area map on the contaminated area range, the depth of contamination, the number of the sensor data classified by the plurality of sites, and the two-dimensional or three-dimensional map of each sensor data based on the data type, the location of the purifier, And a sensor data type selection window for selecting a sensor data type on a contamination map screen including a connection pipe.

When the purifier of the contamination map screen is clicked and selected, the purifier operating screen is displayed, and the purifier operating screen displays the overall configuration of the purifier per tool; A flow indicator selected from the contaminated groundwater flow and tubing injection, brine discharge, sewage discharge of the purifier piping; The operation data table including the pollution degree of each pollutant, the amount of pollution by each city, the water level by the city, the level of the purifier, the pump on / off, the purifier pump on and off, the chemical pump on and off and the normal operation; As a solution to the problem.

The purification apparatus operation screen includes a chart indicating changes in the name of the introduced medicine, the amount of the input medicine to be used, and the amount of the input medicine to be used.

The pump on / off and the purifier pump on / off and the chemical pump on and off can be controlled to be turned on and off, respectively, on the operation screen of the purifier.

A graph showing the trend of the pollution degree change of the pollutant is displayed when the user selects and selects the inflow tank and the discharge tank among the purifiers of the cleaning screen of the purification apparatus.

The automatic control system for purifying apparatus by the real-time monitoring of the IOT-based contaminated groundwater purification apparatus can be confirmed or controlled by online connection to the purification processing construction company or supervisory authority.

The automatic control system of the purification apparatus by the real-time monitoring of the IOT-based contaminated groundwater purification apparatus of the present invention monitors the purification process of the purification apparatus in real time based on the sensor data collected in the process of purifying the contaminated groundwater present in the underground And by automatically controlling the purifier on the basis thereof, there is an excellent effect of achieving an efficient automation of the purifying process and the purifying process.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a schematic view showing the overall configuration of an automatic control system for purifying apparatus by real-time monitoring of an IOT-based contaminated groundwater purification apparatus of the present invention
FIG. 2 is a view showing a contamination map screen of the web dashboard unit of the automatic control system for purifying apparatus by real-time monitoring of the IOT-based contaminated groundwater purification apparatus of the present invention
FIG. 3 is a view showing the operation screen of the purification apparatus of the web dashboard unit of the automatic control system for purifying apparatus by real-time monitoring of the IOT-based contaminated groundwater purification apparatus of the present invention
FIG. 4 is a schematic view showing the operation screen of the purifying device of the web dashboard unit of the automatic control system for purifying apparatus by real-time monitoring of the IOT-based contaminated groundwater purification apparatus of the present invention

The present invention relates to a pollution level sensor, a pH sensor, a temperature sensor, a water level sensor, a water level sensor for measuring pollution degree of a pollution substance connected to an inlet tank and a discharge tank of a plurality of wells excavated and formed for cleaning contaminated groundwater, A sensor unit including a sensor and a rainfall sensor; a server unit for collecting 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, Based on the IOT-based contaminated groundwater purification apparatus, and a web dashboard unit for displaying, in real time, the data for each type of sensor, sensor, and sensor data.

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 degree sensor is characterized in that the degree of pollution is measured using contaminated ground water sampled in a canister or a purification device.

The web dashboard unit displays the contaminated area map on the contaminated area range, the depth of contamination, the number of the sensor data classified by the plurality of sites, and the two-dimensional or three-dimensional map of each sensor data based on the data type, the location of the purifier, And a sensor data type selection window for selecting a sensor data type on a contamination map screen including a connection pipe.

When the purifier of the contamination map screen is clicked and selected, the purifier operating screen is displayed, and the purifier operating screen displays the overall configuration of the purifier per tool; A flow indicator selected from the contaminated groundwater flow and tubing injection, brine discharge, sewage discharge of the purifier piping; The operation data table including the pollution degree of each pollutant, the amount of pollution by each city, the water level by the city, the level of the purifier, the pump on / off, the purifier pump on and off, the chemical pump on and off and the normal operation; And is characterized in that it is constituted by a technical feature.

The purification apparatus operation screen includes a chart indicating changes in the name of the introduced medicine, the amount of the input medicine, and the amount of the input medicine to be used.

The pump on / off and the purifier pump on / off and the chemical pump on and off can be controlled to be turned on and off, respectively, on the operation screen of the purifier.

And a graph showing a trend of changes in the degree of contamination degree of pollutants is displayed when each of the influent tank and the discharge tank among the purifying devices of the purifier moving screen is selected and clicked.

The automatic control system for purifying apparatus by real-time monitoring of the IOT-based contaminated groundwater purification apparatus can be confirmed or controlled by on-line access to the purification 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 automatic control system of the purification apparatus by the real-time monitoring of the IOT-based contaminated groundwater purification apparatus according to the present invention is characterized in that a plurality of wells excavated for purifying groundwater, 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 the pollutants respectively connected to the sensor unit, And a web dashboard unit for displaying the sensor data desired by the user from the server unit in real time in accordance with the respective districts, the purification apparatuses and the sensor data types so that they can be checked or controlled in real time, do.

Here, 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 purgings, 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.

The pollution level sensor measures the degree of pollution using contaminated ground water sampled in a tank or a purifier.

As shown in FIG. 2, the web dashboard unit displays the contaminated area map, the contamination depth, and the number of the sensor data classified by the plurality of sites and the two- or three-dimensional A contaminant map including a water level, an elevation line, an elevation line, an elevation line, an elevation line, an elevation line, an elevation line, an elevation line, an elevation line,

When the purifier of the contamination map screen is clicked and selected, as shown in Fig. 3, the purifier operating screen is displayed, wherein the purifier operating screen displays the overall configuration of the purifier per tool; A flow indicator selected from the contaminated groundwater flow and tubing injection, brine discharge, sewage discharge of the purifier piping; The operation data table including the pollution degree of each pollutant, the amount of pollution by each city, the water level by the city, the level of the purifier, the pump on / off, the purifier pump on and off, the chemical pump on and off and the normal operation; .

In addition, the operation screen of the purifier may include a chart indicating changes in the name of the input medicine, the amount of the input medicine, and the amount of the input medicine.

In addition, the pump on / off, the purifier pump on / off, and the chemical pump on / off of the operation screen of the purifier can be controlled on and off, respectively.

As shown in Fig. 4, when the inflow tank and the discharge tank are selected by clicking the purifier of the purifier moving screen, a graph showing the trend of the pollution degree change of the pollution material is displayed.

It is needless to say that the automatic control system for purifying apparatus according to the real-time monitoring of the IOT-based contaminated groundwater purification apparatus of the present invention is configured to be able to check or control the purification system construction supervisor or the supervisory authority on-line.

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 (11)

A pH sensor, a temperature sensor, a water level sensor, a water level sensor, and a rainfall sensor for measuring pollution degree of a pollutant connected to each of a plurality of wells excavated for contaminated groundwater purification and an inlet tank and a discharge tank of a tool- A server unit for collecting each sensor data transmitted from the sensor unit according to sensor data types; and a server unit for receiving sensor data desired by the user from the server unit, And a web dashboard unit for displaying such that it can be confirmed or controlled in real time for each type,
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 purgers and purged 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; Heavy metal contaminants including arsenic, lead, cadmium, hexavalent chrome, copper, mercury, zinc, nickel, fluorine,
The pollution degree sensor measures pollution degree by using contaminated ground water sampled in a tub or purifier. The pollution degree sensor measures the pollution degree by using gas chromatography (GC), gas chromatography-mass spectrometer (GC-MS), atomic absorption spectrophotometer , An atomic emission photometer, a spectrophotometer, an infrared spectrophotometer, and an ultraviolet spectrophotometer,
The web dashboard unit displays the contaminated area map on the contaminated area range, the depth of contamination, the number of the sensor data classified by the plurality of sites, and the two-dimensional or three-dimensional map of each sensor data based on the data type, the location of the purifier, And a sensor data type selection window for selecting a sensor data type on a contamination map screen including a connection pipe,
Wherein when the purifier of the contamination map screen is clicked and selected, the purifier operating screen is displayed, and the operating screen of the purifier displays the overall configuration of the purifier per tool; A flow indicator selected from the contaminated groundwater flow and tubing injection, brine discharge, sewage discharge of the pipe of the tool-specific purifier; The operation data table including the pollution degree of each pollutant, the amount of pollution by each city, the water level by the city, the level of the purifier, the pump on / off, the purifier pump on and off, the chemical pump on and off and the normal operation; And a control unit for controlling the purifying device based on real-time monitoring of the contaminated groundwater purification apparatus based on IOT
delete delete delete delete delete delete The method according to claim 1,
Wherein the operation screen of the purification apparatus includes a chart indicating changes in the name of the input chemical, the amount of the input chemical, and the amount of the input chemical.
The method according to claim 1,
Wherein the pump on / off and the pump on / off of the pump on / off can be controlled to be on and off, respectively, on the operation screen of the purifier. Automatic device control system
The method according to claim 1,
Wherein when the inflow tank and the discharge tank are selected by clicking each of the purification apparatuses on the moving screen of the purification apparatus, a graph showing a change in the degree of pollution degree of the contaminant is displayed. In the IOT-based contaminated groundwater purification apparatus, Automatic device control system
The method according to claim 1,
Wherein the automatic control system for purifying apparatus based on the real-time monitoring of the IOT-based contaminated groundwater purification apparatus is capable of being confirmed or controlled by on-line access to the purification processing construction company or the supervisory authority for real-time monitoring of the contaminated groundwater purification apparatus based on IOT Automatic control system of purifier

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