KR102478749B1 - Intelligent groundwater well management system - Google Patents

Abstract

The present invention relates to an intelligent groundwater tubular well management system. The system comprises: a plurality of groundwater tubular wells into which groundwater is introduced and stored, and which include a water quality sensor for measuring the quality of introduced groundwater, a soil sensor for detecting the amount of moisture contained in the surrounding soil, and a meteorological sensor for observing precipitation, wind direction, wind speed, temperature, humidity, and atmospheric pressure; a database in which location data of each groundwater tubular well and water intake-related data including daily allowable water intake data of each groundwater tubular well are stored; and a central server which receives sensing values from sensors provided in each groundwater tubular well, reads water intake-related data of each groundwater tubular well from the database, and controls the water intake amount, water intake time, and water intake speed for each groundwater tubular well based on the sensing value and water intake-related data. According to the present invention, the groundwater tubular well management system is provided to exert en effect of monitoring, maintaining, and managing groundwater in real-time as an independent and unified monitoring system in the management of groundwater.

Description

Intelligent groundwater well management system {Intelligent groundwater well management system}

The present invention relates to groundwater well management.

In order to preemptively prepare for increasingly serious water shortages and groundwater pollution, groundwater is a public resource that can be used more stably than surface water. Therefore, through the scientification of the groundwater resource management system, it is necessary to grasp the actual conditions of groundwater administrative data, check the actual number of facilities using groundwater and the amount of use, and strengthen management of public water supply facilities.

However, groundwater management in the prior art has a low utilization rate of digital data and relies on human resources, so there is a problem with a large loss of time and economic cost in recognizing and judging the situation, or an established groundwater-related information management system is also an administrative task in charge of permitting and permitting groundwater. The groundwater usage fee collection rate is sluggish due to the dualization of duties such as the administrative system of the Ministry of Safety and the water billing system of local governments. The groundwater management system, such as the national observation network data system of the Korea Water Resources Corporation, the water quality measurement network data of the Ministry of Environment, and the sewage pipe system of local governments, is diversified. As each institution individually holds and manages water resource data, it is not shared with each other, so related groundwater information is distributed and used in multiple Since the information is managed redundantly, the efficiency of information management is low, so it is inefficient in terms of joint utilization of groundwater information, and the existing groundwater information system built by improving this is simple to the level of computerized management of data, or a business system with each institution Due to the lack of database linkage, in the past, problems such as data linkage, system-specific compatibility, geographic information inconsistency, system scalability, and inconvenience of not supporting integrated modeling techniques in the system have resulted in massive groundwater data and numerous functions. Since it is not easy to integrate them into the system, it is difficult to establish and utilize systematic and standardized groundwater-related data suitable for the domestic situation, so it is difficult to collect and manage groundwater-related information necessary for a specific purpose desired by the user.

Due to the development of underground space, the amount of groundwater leakage has increased by about 18% over the past 10 years (166,000 tons/day in 2011 → 186,000 tons/day in 2020). Inquiries about the use of groundwater in buildings are increasing due to the increase in sewerage fees when discharged groundwater is discharged into the sewerage system, but there is no manual for systematic utilization such as utilization methods and standards. In particular, in the 「Groundwater Act」, the applicable water quality standards for each use of outflow groundwater were ambiguous, resulting in confusion in the application of water quality standards for actual field utilization. Therefore, it is necessary to review various methods for utilization from the planning and design stage of facilities and buildings due to the nature of the runoff groundwater business.

Korean registered patent 10-0676548

The present invention has been made to solve the above problems, and an object of the present invention is to provide a groundwater well management system capable of real-time monitoring and maintenance as an independent and unified monitoring system in groundwater management.

The object of the present invention is not limited to the object mentioned above, and other objects not mentioned will be clearly understood by those skilled in the art from the description below.

The present invention for achieving the above object relates to a groundwater well management system, in which groundwater is introduced and stored, a water quality sensor for measuring the water quality of the inflowed groundwater, and a soil sensor for detecting the amount of moisture contained in the surrounding soil. and water intake-related data including a plurality of groundwater wells equipped with meteorological sensors for observing precipitation, wind direction, wind speed, temperature, humidity, and atmospheric pressure, location data of each groundwater well, and daily allowable water intake data of each groundwater well. Receives sensing values from the database and sensors provided in each groundwater well, reads water intake-related data of each groundwater well from the database, and receives water intake for each groundwater well based on the sensing values and water intake-related data. , and includes a central server that controls water intake time and water intake speed.

Each of the groundwater wells includes a water quality sensor for measuring the quality of the inflowed groundwater, a soil sensor for detecting the amount of moisture contained in the surrounding soil, a meteorological sensor for observing precipitation, wind direction, wind speed, temperature, humidity, and atmospheric pressure, wired and wireless A communication unit for communicating with an external device through a communication network, a photovoltaic module for supplying power using sunlight, and controlling the driving of the water quality sensor, soil sensor, and weather sensor, and controlling the driving of the solar module, A control device configured to communicate with the central server through the communication unit may be included.

The central server monitors the status of each groundwater well in real time, visualizes monitoring information on each groundwater well, provides it to a terminal, and controls so that water is taken into a separate storage tank according to the amount of water intake set for each groundwater well. can

The central server may output an alarm alarm and transmit an alarm message to a manager's terminal when the water level or groundwater quality of the groundwater well exceeds a predetermined reference value.

According to the present invention, by providing a groundwater well management system, real-time monitoring and maintenance are possible as an independent and unified monitoring system in groundwater management.

1 conceptually illustrates the configuration of a groundwater well management system according to an embodiment of the present invention.
2 is a block diagram showing the internal structure of an underground water well according to an embodiment of the present invention.
3 is a flowchart illustrating a groundwater well management method in the groundwater well management system according to an embodiment of the present invention.
4 is an example of a screen displaying a map showing locations of groundwater wells and information related to groundwater wells according to an embodiment of the present invention.
5 is an example of a screen displaying a state of a raw water storage tank according to an embodiment of the present invention.
6 is an example of a screen displaying information and an operating program of each groundwater well according to an embodiment of the present invention.
7 and 8 are actual groundwater well enclosures according to an embodiment of the present invention.
9 illustrates an LCD screen in an actual groundwater well enclosure according to an embodiment of the present invention.

Since the present invention can make various changes and have various embodiments, specific embodiments will be illustrated in the drawings and described in detail. However, this is not intended to limit the present invention to specific embodiments, and should be understood to include all modifications, equivalents, and substitutes included in the spirit and scope of the present invention.

Terms used in this application are only used to describe specific embodiments, and are not intended to limit the present invention. Singular expressions include plural expressions unless the context clearly dictates otherwise. In this application, the terms "include" or "have" are intended to designate that there is a feature, number, step, operation, component, part, or combination thereof described in the specification, but one or more other features It should be understood that the presence or addition of numbers, steps, operations, components, parts, or combinations thereof is not precluded.

Unless defined otherwise, all terms used herein, including technical or scientific terms, have the same meaning as commonly understood by one of ordinary skill in the art to which the present invention belongs. Terms such as those defined in commonly used dictionaries should be interpreted as having a meaning consistent with the meaning in the context of the related art, and unless explicitly defined in the present application, it should not be interpreted in an ideal or excessively formal meaning. don't

In addition, in the description with reference to the accompanying drawings, the same reference numerals are given to the same components regardless of reference numerals, and overlapping descriptions thereof will be omitted. In describing the present invention, if it is determined that a detailed description of related known technologies may unnecessarily obscure the subject matter of the present invention, the detailed description will be omitted.

1 conceptually illustrates the configuration of a groundwater well management system according to an embodiment of the present invention.

Referring to FIG. 1 , the groundwater well management system of the present invention includes a plurality of groundwater wells 100 , a database 210 , and a central server 200 .

In the groundwater well 100, groundwater is introduced and stored, a water quality sensor for measuring the quality of the inflowed groundwater, a soil sensor for detecting the amount of moisture contained in the surrounding soil, and precipitation, wind direction, wind speed, temperature, humidity, and air pressure. It is equipped with a meteorological sensor for observing.

The database 210 stores water intake-related data including location data of each groundwater well and daily allowable water intake data of each groundwater well.

The central server 200 receives sensing values from sensors provided in each groundwater well 100, reads water intake-related data of each groundwater well from the database 210, and receives each groundwater intake-related data based on the sensing values and water intake-related data. Control the water intake amount, water intake time and water intake rate for groundwater wells.

The central server 200 monitors the conditions of each groundwater well 100 in real time, visualizes monitoring information on each groundwater well, provides it to the terminal, and supplies water intake to a separate storage tank according to the amount of water intake set for each groundwater well. You can control it to happen.

The central server 200 may output an alarm alarm and transmit an alarm message to a manager's terminal when the water level or groundwater quality of the groundwater well 100 exceeds a predetermined reference value.

2 is a block diagram showing the internal structure of an underground water well according to an embodiment of the present invention.

Referring to FIG. 2 , the groundwater well 100 includes a water quality sensor 110, a soil sensor 120, a weather sensor 130, a control device 140, a communication unit 150, and a solar module 160. .

The water quality sensor 110 serves to measure the quality of the introduced groundwater.

Soil sensor 120 serves to detect the amount of moisture, soil temperature, electrical conductivity, etc. contained in the surrounding soil.

The weather sensor 130 serves to observe precipitation, wind direction, wind speed, temperature, humidity, and air pressure.

The communication unit 150 serves to communicate with an external device through a wired or wireless communication network. For example, the communication unit 150 may be implemented in IoT (LoRa), WCDMA, 4G LTE, and the like.

The solar module 160 serves to supply power using sunlight.

The control device 140 controls the operation of the water quality sensor 110, the soil sensor 120, and the weather sensor 130, controls the operation of the solar module 160, and controls the operation of the solar module 160, and through the communication unit 150, the central server ( 200) to communicate.

3 is a flowchart illustrating a groundwater well management method in the groundwater well management system according to an embodiment of the present invention. The central server 200 performs the groundwater well management method of FIG. 3 .

Referring to FIG. 3 , the central server 200 prioritizes water intake in the order of groundwater wells with high heights above sea level to low groundwater tubes based on the height (s) above sea level of the bottom of the groundwater tubes within a predetermined area (S301). .

In addition, each subsurface well is classified into an adjacent area group (A) adjacent to a river or stream and a non-adjacent area group (B) that are not adjacent to the river or stream. The method is as follows. First, if the height (s) of the bottom of the groundwater well is lower than the flood level of the river or stream within a predetermined area (S303), and the distance from the river or stream outline at the time of flood is within the reference distance (a) (S305), the groundwater well is classified as an adjacent region group (A) (S307). And, if the height (s) of the bottom of the groundwater well is higher than the flood level of the river or stream within the predetermined area (S303), or the distance from the river or stream outline at the time of flood exceeds the reference distance (a) (S305) , the groundwater well is classified as a non-adjacent area group (B) (S309).

In addition, with respect to the groundwater wells classified as the adjacent area group (A) and the groundwater wells classified as the non-adjacent area group (B), different reference values are applied to each group to determine whether to take in water.

First, in the groundwater well belonging to the adjacent area group (A), if the hourly precipitation exceeds the first predetermined standard precipitation amount (b1) (S311), and the groundwater well water level exceeds the predetermined first standard water level (d1) ( S313), and water intake is started for the corresponding groundwater well (S327).

Alternatively, in the groundwater well belonging to the adjacent area group (A), the hourly precipitation has a value between the first reference precipitation amount (b1) and the second reference precipitation amount (c1) (S311, S315), and the groundwater well water level is the first reference water level If it has a value between (d1) and the second reference water level (e1) (S313, S317), water intake is started for the corresponding groundwater well (S327). At this time, b1>c1 and d1>e1.

In addition, in the groundwater well belonging to the non-adjacent area group (B), if the hourly precipitation exceeds the predetermined third standard precipitation amount (b2) (S319) and the groundwater well water level exceeds the predetermined third standard water level (d2) (S321), water intake is started for the groundwater well (S327).

Alternatively, in the groundwater well belonging to the non-adjacent area group (B), the hourly precipitation has a value between the third standard precipitation (b2) and the fourth standard precipitation (c2) (S319, S323), and the groundwater well water level is the third standard If it has a value between the water level d2 and the fourth reference water level e2 (S321 and S325), water intake is started from the groundwater well (S327). At this time, b2>c2 and d2>e2.

4 is an example of a screen displaying a map showing locations of groundwater wells and information related to groundwater wells according to an embodiment of the present invention.

Referring to FIG. 4, the state of groundwater wells is displayed in color on the map. Green indicates that all states are normal, yellow indicates that data has not been measured during inspection, and red indicates that an error has occurred and requires inspection. .

And, in the screen example of FIG. 4, the instantaneous flow rate, today's water intake, cumulative water intake, water level, and status information for each groundwater well are displayed on the right side. As shown in FIG. 4 , in general, the permissible daily water intake is legally set for each groundwater well.

5 is an example of a screen displaying a state of a raw water storage tank according to an embodiment of the present invention.

Referring to FIG. 5 , various types of information including the water level of each raw water storage tank are displayed. In the present invention, raw water taken from each groundwater well is stored in a raw water storage tank in order to comply with the permissible daily intake amount set by law in each groundwater well.

6 is an example of a screen displaying information and an operating program of each groundwater well according to an embodiment of the present invention.

Referring to FIG. 6, the node ID of each groundwater well, node name, pump status, groundwater well information, water intake control, groundwater well level, water level control, water tank control or time control, and final reception time information are displayed. there is.

In the present invention, each groundwater well can be automatically operated in conjunction with a raw water storage tank, in conjunction with daily legal water intake setting information, in association with the groundwater well level, and in association with arbitrarily set operation time information. Alternatively, if necessary, each groundwater well may be manually set and operated arbitrarily.

7 and 8 show an actual groundwater well enclosure according to an embodiment of the present invention, and FIG. 9 shows an LCD screen in an actual groundwater well enclosure according to an embodiment of the present invention.

In the examples of FIGS. 7 to 9, the appearance of an actual groundwater well is shown, commercial power is supplied, wireless communication is possible, information is updated on the LCD screen at 1-minute intervals, and water intake, water level, and pump operation are displayed. controlled automatically. And, the LCD screen of the groundwater well displays the instantaneous value, the daily integrated value, and the total accumulated value for the intake of each groundwater well, and the natural water level information and pump status of the groundwater well are displayed.

The present invention has been described above using several preferred embodiments, but these embodiments are illustrative and not limiting. Those skilled in the art to which the present invention pertains will understand that various changes and modifications can be made without departing from the spirit of the present invention and the scope of rights set forth in the appended claims.

100 Groundwater Wells 200 Central Server
210 database 110 water quality sensor
120 Soil Sensor 130 Weather Sensor
140 control unit 150 communication unit
160 solar modules

Claims (4)

Groundwater is inflowed and stored, a water quality sensor to measure the quality of the inflowed groundwater, a soil sensor to detect the amount of moisture contained in the surrounding soil, and a meteorological sensor to observe precipitation, wind direction, wind speed, temperature, humidity, and atmospheric pressure. A plurality of groundwater wells having;
a database storing water intake-related data including location data of each groundwater well and data of daily allowable water intake of each groundwater well; and
Sensing values are received from sensors provided in each of the groundwater wells, water intake-related data of each groundwater well is read from the database, and water intake amount, water intake time, and Including a central server that controls the water intake speed,
Each of the groundwater wells,
a water quality sensor for measuring the quality of inflowed groundwater;
Soil sensor for detecting the amount of moisture contained in the surrounding soil;
meteorological sensors for monitoring precipitation, wind direction, wind speed, temperature, humidity, and atmospheric pressure;
A communication unit for communicating with an external device through a wired or wireless communication network;
A solar module for supplying power using sunlight; and
A control device for controlling driving of the water quality sensor, soil sensor, and weather sensor, controlling driving of the photovoltaic module, and communicating with the central server through the communication unit,
The central server monitors the status of each groundwater well in real time, visualizes monitoring information for each groundwater well, provides it to a terminal, controls water intake to a separate storage tank according to the amount of water intake set for each groundwater well, ,
The central server outputs an alarm alarm when the water level or groundwater quality of the groundwater well exceeds a predetermined reference value, and transmits an alarm message to a manager's terminal;
The central server prioritizes water intake in the order of groundwater wells with high heights above sea level to low groundwater wells based on the height (s) above sea level of the groundwater well bottom within a predetermined area,
The central server classifies each groundwater well into an adjacent area group (A) adjacent to a river or stream and a non-adjacent area group (B) that are not adjacent to a river or stream, but the height (s) of the bottom of the groundwater well is a river or stream within a predetermined area. If it is lower than the flood level of and the distance from the river or stream outline at the time of flood is within the standard distance (a), the groundwater well is classified as an adjacent area group (A), and the height (s) of the bottom of the groundwater well is a predetermined area If it is higher than the flood level of the river or stream within, or if the distance from the river or stream outline exceeds the standard distance (a) at the time of flood, the groundwater well is classified as non-adjacent area group (B),
The central server determines whether or not to take in water by applying different reference values for each group to groundwater wells classified as adjacent area group (A) and groundwater wells classified as non-adjacent area group (B),
When b1>c1 and d1>e1,
In the groundwater well belonging to the adjacent area group (A), if the hourly precipitation exceeds the predetermined first standard precipitation amount (b1) and the groundwater well water level exceeds the predetermined first standard water level (d1), for that groundwater well to initiate intake,
In the groundwater well belonging to the adjacent area group (A), the hourly precipitation has a value between the first reference precipitation amount (b1) and the second reference precipitation amount (c1), and the groundwater well water level is between the first reference water level (d1) and the second reference water level (d1). If it has a value between the reference water level (e1), start water intake for the groundwater well,
When b2>c2 and d2>e2,
In the groundwater well belonging to the non-adjacent area group (B), if the hourly precipitation exceeds the predetermined third standard precipitation amount (b2) and the groundwater well water level exceeds the predetermined third standard water level (d2), the corresponding groundwater well to initiate intake for
In the groundwater well belonging to the non-adjacent area group (B), the hourly precipitation has a value between the third standard precipitation (b2) and the fourth standard precipitation (c2), and the groundwater well water level is equal to the third standard water level (d2) and the third standard precipitation (d2). If it has a value between the 4 standard water levels (e2), the groundwater well management system characterized in that to start water intake for the groundwater well.
delete delete delete

Images