KR20100069397A - Management system for hydrologic circle of drainage area - Google Patents

Abstract

PURPOSE: A hydrological cycle management system of river valley is provided to monitor and control a hydrological cycle of an urban district. CONSTITUTION: A UMS server(6) notifies error generating information from a collection server and leakage generating information and leakage generating location information transmitted from a operation/analysis server to a corresponding manager through voice, character, facsimile, and e-mail. A web server(14) performs user authentication of a connected user. The web server gives an access level to the authenticated user. A manager terminal(18) is provided information from a database through the web server. The manager terminal offers the provided information to a manager managing a hydrological cycle of river valley.

Description

Management System for Hydrologic Circle of Drainage Area

The present invention relates to a water circulation management system of the watershed, and in particular, by integrating and managing a water supply facility and a sewage treatment facility to enable monitoring and control of the water circulation in an urban area, and to reduce manpower and management costs for facility management. It is possible to reduce the amount of water used in drinking water treatment by predicting the constant demand demand at the final consumer, and to efficiently manage the chemical and incidental costs of drinking water treatment, and to manage the treatment cost and the amount of sludge generated in the sewage treatment plant. It is about the water circulation management system of the watershed.

In general, the water supplied to homes or buildings in urban areas is supplied to water purification plants through intake pipes from raw water pools, such as dams and streams, and the water purification plants collect the required amount of raw water from the raw water and supply physical water. • Purifies by chemical and biological methods.

On the other hand, the purified water from the water treatment plant is supplied to the drainage through the water pipe, and the drainage is temporarily stored in the purified water supplied from the water purification plant, and when there is a demand for water supply from the final consumer (eg, home, building, etc.) Release through the drain pipe (water pipe network) as required.

The final consumer uses the water supply from the reservoir through the drainage pipe and discharges it to the sewage treatment plant through the sewage pipe, and the sewage treatment plant purifies the sewage drained from the final consumer through the sewage pipe by physical, chemical and biological methods. Release.

On the other hand, in urban areas that use water, such as homes or buildings, rainwater is discharged from the downtown area to the river through rainwater pipes.

As such, water is discharged from the raw water to the water purification plant, the water treatment plant to the drainage station, the water reservoir to the final consumer at the sewage treatment plant, the sewage treatment plant to the river, and the river to the ocean.

Accordingly, in order to facilitate the circulation of the water used in the urban area as described above, a water supply facility for supplying water from the source water to the final consumer and a sewage treatment facility for purifying the water used in the final consumer and discharging it to the stream are integrated and managed. It is desirable to be.

However, conventionally, only a system for separately managing a water treatment plant, a water pipe, a sewage pipe, a sewage treatment plant, or a separate water and sewage treatment facility has been developed, and there is no system for integrating and managing a water supply facility and a sewage treatment facility. Situation.

For this reason, in the related art, it is difficult to monitor and control a series of water circulations in which a water supply facility and a sewage treatment facility are respectively managed or only a water pipe or a sewer pipe is discharged from a raw water source to a sewage treatment plant via a final consumer.

In addition, since the conventional water and sewage treatment facilities are separately managed, a large number of personnel must be employed for separate management of the water and sewage treatment facilities, thereby increasing the management cost for managing the water and sewage treatment facilities. .

Accordingly, the present invention is to solve the above problems, by integrating and managing the water supply and sewage treatment facilities to enable the monitoring and control of the water circulation in the urban area, manpower and management costs for facility management The aim is to provide a watershed management system for watersheds that can be reduced.

In addition, the present invention can determine the supply amount in the water purification plant by predicting the constant demand required at the final consumer price to efficiently manage the chemicals and incidental costs for drinking water treatment, as well as to manage the treatment cost and the amount of sludge generated in the sewage treatment plant. To provide a water circulation management system for existing watersheds.

Water circulation management system of the basin according to an embodiment of the present invention is installed in the raw water, water purification plant, drainage, sewage treatment plants, rivers, water pipes and sewer pipes, respectively, and the water quality, quantity, water pressure, water level, flow rate and leakage of water and sewage in real time. Field measuring instrument; Collects data measured from the field measuring instrument in real time through a wired / wireless communication network, and if an error occurs in the measuring data transmitted from the field measuring instrument, requests the field measuring instrument to retransmit the measurement data, and corrects through filtering of abnormal data Collecting server to perform; A GIS server that provides geographic information including the area, housing type, topography, soil, pipe network, specifications of conduits, and current status of attached facilities of the area and the population information of the area; Measurement data including the water quality, quantity, water pressure, water level, flow rate and leakage, constant usage used in the final consumer, average daily usage per person using geographic information and / or population information transmitted from the GIS server, 1 Average daily water supply, maximum daily water supply per person, maximum water supply per hour, constant demand in the area, purified water to be purified at the water purification plant, power required to purify the raw water, cost of the raw water purification, chemicals necessary for the raw water purification Water input, water consumption, sewage treatment cost, chemical input for sewage treatment, power required for sewage treatment, location of leakage, leakage, intrusion and inflow, daily maximum / minimum flow, daily average flow , Inflow into the water purification plant, outflow from the water purification plant, inflow into the drainage basin, outflow from the drainage basin, leakage from the water supply pipe Amount, location of leakage of the water pipe, inflow into the water pipe, leakage from the sewage pipe, pollution load, intrusion water intrusion into the sewage pipe or sewage treatment plant, the amount of sewage generated in the final customer, leakage occurs in the sewer pipe A calculation / analysis server for calculating a location; Measurement data collected by the collection server in real time, the constant amount of water used in the final customer, the average daily consumption per person transmitted from the calculation / analysis server, the average daily water supply per person, the maximum daily water supply per person, 1 Maximum water supply per capita, local water demand, purified water to be purified at the water purification plant, power required to purify the raw water, the cost of the raw water purification, chemical input required for the raw water purification, the cost of using the constant water by the final consumer, sewage and sewage treatment costs , Chemical input required for sewage treatment, power required for sewage treatment, leakage location, leakage generation amount, intrusion and inflow quantity, daily maximum / minimum flow rate, daily average flow rate, inflow into the water treatment plant, outflow from the water purification plant, the Inflow into the sump, outflow from the sump, leakage from the water pipe, leak location of the water pipe, the phase Flow rate flowing into the tube, leakage of the sewage pipe, pollution load, sewers or be invasive intrusion into a sewage treatment plant quantities, generated in the final suyongga sewage water amount, a database that stores the leak position in the sewer; A UMS server that notifies the manager in charge of error occurrence information from the collection server, leak occurrence information and leak occurrence location information transmitted from the calculation / analysis server by voice, text, fax, and e-mail; A web server performing user authentication of a connecting user and granting an access level to an authenticated user; And a manager terminal receiving the information from the database through the web server and providing the manager to manage the water circulation in the watershed.

In the water circulation management system of the watershed according to the embodiment of the present invention, the calculation / analysis server receives the population information from the GIS server 12 and uses the past population information and the current population information in the corresponding area in the transmitted population information. Then, the population growth rate of the region and the expected population of the region are calculated in a specific year, and the calculated constant demand for the region in the specific year is calculated by using the calculated estimated population of the region and the constant consumption by the end user.

In the water circulation management system of the basin according to an embodiment of the present invention, the calculation / analysis server uses a time series estimating method of any one of an equal order, equal order, cutting function, exponential function, logistic, and correction index as shown in Equation 1 below. Calculate the estimated population in your area.

(Equation 1)

Differential Grade: y = a (bx + 1)

Equivalence: y = a (1 + b) ^x

Slash function: y = a (1 + b) ^x + c

Exponential function: y = ax ^b + c

Logistic: y = k / (1 + e ^a-bx )

Correction index: y = k-ab ^x

Where y is the expected population for a particular year, a and c are the current population, b is the population growth rate, x is the number of years old, and k is the limit.

In the water circulation management system of the basin according to an embodiment of the present invention, the manager terminal is the water quality, quantity, water pressure, water level, flow rate and leakage of the constant and sewage from the database, the opening and closing information of the water pipe and sewage pipe, 1 person 1 day Average consumption, daily average water supply per person, maximum daily water supply per person, maximum water supply per hour, constant demand in the area, purified water to be purified at the water purification plant, power required for purification of the raw water, cost of the raw water purification, the raw water Chemical input required for purification, water consumption for each final consumer, sewage, sewage treatment cost, chemical input for sewage treatment, power required for sewage treatment, location of leakage, leakage, intrusion and inflow, daily maximum / minimum flow rate , Daily average flow rate, inflow into the water purification plant, outflow from the water purification plant, inflow into the drain, the outflow from the drain, Leakage amount from the water pipe, leak location of the water pipe, inflow into the water pipe, leakage from the sewage pipe, pollutant load, the amount of intrusion into the sewage pipe or sewage treatment plant, the amount of sewage generated from the final customer, the Provide location of leaks in sewer pipes.

In the water circulation management system of the basin according to an embodiment of the present invention, the manager terminal transmits the change of the geographic information and / or population information to the GIS server, and the GIS server is the geographic information transmitted from the manager terminal. And / or update and store changes in population information, and provide the updated geographical information and / or population information to the computation / analysis server.

In the water circulation management system of the watershed according to an embodiment of the present invention, the manager terminal receives the user authentication through the web server and then controls the operation of the switchgear installed in the water pipe and the sewer pipe, and the supply quantity of the water pipe and the Adjust the discharge amount of sewer pipes.

Water basin water circulation management system according to an embodiment of the present invention after receiving the user authentication through the web server is provided with the constant amount of use, constant water quality, cost of using the constant, water saving time, water saving period from the database, And a user terminal for transmitting a complaint of the user to the database through the web server.

In the water circulation management system of the watershed according to an embodiment of the present invention, the database provides user complaint information transmitted through the user terminal to the manager terminal through the web server.

The present invention monitors the water circulation in urban areas because it integrates and manages the water supply facilities for supplying water from the raw water to the final consumer and the sewage treatment facility for discharging sewage and sewage discharged from the final consumer to sewage treatment plants and streams. In addition to real-time control, integrated management of water and sewage treatment facilities can reduce manpower and management costs for facility management.

In addition, the present invention can determine the constant water supply in the water purification plant through the prediction of the constant amount of water used in the final consumer can not only efficiently manage the chemicals and incidental costs required for drinking water treatment, but also generated by each sewage treatment segment. Since the amount of inflow into the sewage treatment plant is controlled by real-time monitoring of the amount of sewage, it is possible to predict and manage the cost of sewage treatment and the amount of sludge generated such as chemicals used for sewage treatment.

In addition, since the present invention measures the amount of sewage generated by each sewage treatment basin in real time, the treatment basin which generates the most infiltration water and inflow water included in the inflow flow rate of the sewage treatment plant is compared with the inflow amount of the sewage treatment plant. By searching, you can not only know the contribution of the treatment branch, but also select and manage the treatment branches that cause the most problems.

In addition, the present invention can reduce the water saving time as well as shorten the water saving time because it can be supplied by properly adjusting the constant supply amount supplied to the final consumer in the drainage in the event of a water supply disruption due to the contamination of the raw water, it occurs in the water supply pipe and sewage pipe Since the leakage is monitored in real time, it is easy to find the section in which the leak occurred, thereby reducing the cost incurred by the leak.

In addition, the present invention calculates the population of the region in a particular year and then predicts the amount of water demand required for the region in a given year through the estimated consumption of the region and the final consumption of the final consumer. Policy decisions and budgets for sewage treatment plants can be used as a more scientific basis for decision-making and budget execution for demand, as well as forecasting the inflow and water quality of sewage treatment plants from sewage and water quality discharged from the final consumer. It can be used as basic data for execution.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a view showing a water circulation management system of the watershed according to an embodiment of the present invention.

Referring to FIG. 1, a water circulation management system of a watershed according to an embodiment of the present invention includes a plurality of field meters 2, a collection server 4, a database (hereinafter referred to as “DB”) 8, and calculations. / Analysis server 10, Geographic Information System (GIS) server 12, UMS server 6, web server 14, administrator terminal 18 and user terminal 16 .

The plurality of field meters 2 may include a raw water source, a water purification plant, a drainage basin, a sewage treatment plant, and a water intake pipe installed between the stream and the raw water reservoir and the water purification plant, a water pipe installed between the water purification plant and the drainage basin, and the drainage basin and the final consumer (for example, Buildings, etc.), drainage pipes installed between the final consumer and the sewage treatment plant, and rainwater pipes installed between the final consumer area (city or rural area) and rivers, respectively, to provide water quality and quantity of water and sewage. Measure water pressure, water level, flow rate and leaks in real time.

Here, the intake pipe, the water pipe and the drain pipe are water pipes for supplying water to the final customer, and the sewage pipes and storm water pipes are sewage pipes that discharge used sewage or rainwater.

On the other hand, the water pipe and sewage pipes are provided with an opening and closing device (not shown) for opening and closing the water pipes and sewage pipes according to a control signal transmitted from the outside, the opening and closing device is wired or wireless communication whether the water pipes and sewage pipes Send to the collection server (4) through.

At this time, the measurement data measured by the plurality of field measuring instruments 2 in real time is transmitted to the collection server 4 through a wired or wireless communication network.

The collection server 4 collects the data measured from the field measuring instrument 2 and whether the water pipe and the sewer pipe are opened or closed in real time through a wired or wireless communication network, and an error is detected in the measured data transmitted from the field measuring instrument 2. If necessary, re-transmission of the measurement data is requested to the field meter 2, and correction through filtering of the abnormal data is performed.

The collection server 4 generates an error generation signal and transmits the generated error signal to the UMS server 6 when an error occurs in the measurement data transmitted from the field measuring instrument 2.

The DB (8) is measured data such as water quality, quantity, water pressure, water level, flow rate and leakage of the constant and sewage collected in real time by the collection server 4 (including the opening and closing information of the water pipe and sewage pipe), Data transmitted from the calculation / analysis server 10 (for example, daily average water consumption per person, daily average water supply per person, maximum daily water supply per person, maximum water supply per hour per hour, constant demand for the region, water purification plant The amount of purified water to be purified, the power required for the purification of the raw water, the cost of the raw water purification, the chemical input required for the raw water purification, the constant use cost by the final consumer, the amount of sewage, the amount of sewage treatment, the amount of chemicals required for sewage treatment, the sewage treatment Power, location of leakage, leakage, amount of intrusion and inflow, daily maximum / minimum flow rate, daily average flow rate, inflow into the water purification plant, outflow from the water purification plant, inflow into the drainage basin, The amount of outflow from the reservoir, the amount of leakage from the water supply pipe, the location of leakage of the water supply pipe, the amount of inflow into the water supply pipe, the amount of leakage from the sewage pipe, the amount of contamination, the amount of intrusion into the sewage pipe or the sewage treatment plant The amount of sewage generated in the water supply system, the location of the leak in the sewer pipe, etc.) and the constant amount of water used by the final consumer transmitted from the user terminal 16 and / or the manager terminal 18 in a chart, table, and graph ( In the form of graph), it is classified and stored by hourly, daily, monthly, quarterly and yearly.

At this time, the constant amount of water used by the final consumer is classified by use (for example, household, business, business, industrial, etc.) and stored in the DB 8.

In addition, the DB (8) includes a constant cost per unit volume transmitted from the manager terminal 18, the cost of sewage treatment per unit volume, the amount of medicine required to treat the unit volume of sewage, the power required to purify the raw water of the unit volume, Information such as the power required to treat the unit volume of sewage is stored.

The GIS server 12 is the area of the relevant area, residential form (rural, fishing village, industrial complex, apartment, dense residential area, etc.), terrain, soil (residential, green area, etc.), pipe network (ie, water pipe and sewer pipe) It provides geographical information such as pipe network diagram, specifications of conduits (extension by tube diameter, tube type, diameter, etc.), current status of attached facilities (eg manholes, etc.) and population information of the area.

The GIS server 12 receives the geographic information and / or population information from the outside and provides the geographic information and / or population information to the calculation / analysis server 10 or the geographic information and / or population information stored therein. Provided in (10).

In other words, when the GIS server 12 transmits geographic information and / or population information from the manager terminal 18 through the web server 14, the GIS server 12 transmits geographic information and / or population from the manager terminal 18. Information is provided to the calculation / analysis server 10 or geographic information and / or population information stored therein is provided to the calculation / analysis server 10.

On the other hand, the geographic information and / or population information provided by the GIS server 12 is changed according to geographic information and / or population information transmitted from the outside.

In other words, when the GIS server 12 transmits geographic information and / or population information from the manager terminal 18 through the web server 14, the GIS server 12 transmits the geographic information and / or population information stored therein to the manager terminal ( 18) and update with the geographic information and / or population information transmitted from the store and internally.

The calculation / analysis server 10 receives measurement data such as water quality, quantity, water pressure, water level, flow rate, and leakage from the DB 8 and constant usage amount for each end user from the DB 8, and the GIS server 12 ) Is a numerical program stored internally by receiving geographic information and / or population information from), the average daily consumption of water per person, average daily water supply per person, maximum water supply per person per day, maximum water supply per hour per hour, and constant water demand in the area , The amount of purified water to be purified in the water treatment plant, the power required for the purification of the raw water, the cost of the raw water purification, the amount of chemicals required for the purification of raw water, the cost of using the constant water by the end user, the amount of sewage, the amount of sewage treatment, the amount of chemicals required for sewage treatment, sewage treatment It calculates the power required, the location of leakage occurs, the amount of leakage occurs, the amount of intrusion and inflow, the daily maximum / minimum flow rate, the daily average flow rate, and transmits the calculated information to the DB (8).

Here, the constant usage cost for each final consumer is calculated by multiplying the constant consumption used in the final consumer by the constant cost per unit volume transmitted from the DB (8).

In order to calculate the constant demand amount of the corresponding area, the calculation / analysis server 10 first receives the population information from the GIS server 12 and transmits the previous population information and the current population in the corresponding area from the transmitted population information. Using the information, internally stored numerical programs calculate the population growth rate of the region and the expected population for that region in a particular year.

In this case, the calculation / analysis server 10 calculates an estimated population of the corresponding region using any one of time series estimation methods of equal order, equal order, cutting function, exponential function, logistic, and correction index.

Here, the graded grade, the graded grade, the cutting function, the exponential function, the logistic, and the correction index are shown in Equation 1.

Differential Grade: y = a (bx + 1)

Equivalence: y = a (1 + b) ^x

Slash function: y = a (1 + b) ^x + c

Exponential function: y = ax ^b + c

Logistic: y = k / (1 + e ^a-bx )

Correction index: y = k-ab ^x

Where y is the expected population for a particular year, a and c are the current population, b is the population growth rate, x is the number of years old, and k is the extreme value.

Meanwhile, the calculation / analysis server 10 calculates an estimated population of the region in a specific year as described above, and then calculates the necessary population for the region in a specific year by using the calculated constant usage for each region and the estimated population of the region. Calculate the constant demand.

In this case, the calculation / analysis server 10 calculates both the constant demand amount for each use (for example, household, business, business, industrial, etc.) and the total constant capacity without considering the use.

The calculation / analysis server 10 calculates the amount of water supply to be supplied from the water purification plant to the corresponding region and the amount of generated sewage to be generated in the corresponding region, based on the calculated constant demand, and is supplied from the water purification plant supply and the DB 8. The water quality information of the water purification plant is used to calculate the power required for raw water purification, chemical input required for raw water purification, and raw water purification cost, and the sewage treatment plant uses the generated sewage amount and water quality information of the sewage treatment plant transmitted from the DB (8). Calculate the power, chemical inputs and sewage treatment costs needed for sewage treatment.

In addition, the calculation / analysis server 10 receives the constant usage by the final consumer from the DB (8) by the numerical program stored in the internal daily average usage per person, average daily water supply per person, maximum daily per person Calculate the water supply and maximum water supply per person.

In this case, the average daily consumption of a person is calculated as the ratio of daily average water consumption of the final consumer to the number of populations in the region, and the average daily consumption of water per person is equivalent to the daily average water supply from which the final consumer receives water from the reservoir. The maximum daily water supply per person is calculated as the ratio of the maximum daily water supply to which the final consumer receives water from the basin and the population of the region. It is calculated as the ratio of the maximum amount of water supplied per hour to the number of people in the area.

In addition, the calculation / analysis server 10 is the measurement data such as water quality, quantity, water pressure, water level, flow rate and leakage transmitted from the DB (8) by the field meter (2) Measurement data measured in the pipe) and opening / closing information of the water pipe and the geographic information transmitted from the GIS server 12 to the numerical program stored therein, the inflow into the water purification plant, the outflow from the water purification plant, the drainage reservoir Information about the flow rate of the inlet, the amount of outflow from the reservoir, the amount of leakage from the water supply pipe, the location of leakage of the water supply pipe, the amount of inflow into the water supply pipe and the like are calculated.

And, the calculation / analysis server 10 is measured data such as the water quality, quantity, water pressure, water level, flow rate and leakage transmitted from the DB (8 (sewage pipe, river and sewage treatment plant by the field measuring instrument 2) Measured data measured only) and the numerical program stored inside using the opening and closing information of the sewage pipe and the geographic information transmitted from the GIS server 12, the amount of leakage from the sewage pipe, the contamination load, the intrusion water intrusion into the sewage pipe or sewage treatment plant To calculate the amount of sewage generated in the final customer, the location of leakage in the sewer pipe and the like.

On the other hand, the calculation / analysis server 10 calculates the location of the leak occurs in the water supply pipe or sewage pipe when the leak occurs in the water supply pipe or sewer pipe, and the leakage information and the leakage location of the UMS server (6) To transmit.

Accordingly, the UMS server 6 notifies the manager in charge of leak occurrence information and the leak occurrence position transmitted from the calculation / analysis server 10 by voice, text, fax, or e-mail.

Such, the calculation / analysis server 10 is the average daily consumption of water per person, daily average water supply per person, maximum daily water supply per person, maximum water supply per hour, constant demand in the area, the amount of water to be purified in the water purification plant , The power required for the purification of the raw water, the cost of the raw water purification, the chemical input required for the raw water purification, the constant use cost by the final consumer, the sewage amount, the sewage treatment cost, the chemical input required for sewage treatment, the power required for sewage treatment, leakage occurs Location, leakage, inflow and inflow, daily maximum / minimum flow rate, daily average flow rate, inflow into the water purification plant, outflow from the water purification plant, inflow into the drainage basin, outflow from the drainage basin, Leakage amount, leak location of the water pipe, inflow into the water pipe, leakage from the sewage pipe, pollution load, infiltration into the sewage pipe or sewage treatment plant Calculates information such as the amount of intrusion, the amount of sewage generated at the final customer, the location of the leak in the sewer pipe, and transmits the calculated information to the DB 8, and the DB 8 calculates and analyzes the information. The information transmitted from the server 10 is stored therein.

When the UMS server 6 transmits an error occurrence signal from the collection server 4 (that is, an abnormal state of the field measuring device 2 is detected), the UMS server 6 notifies the manager in charge of voice, text, fax, and e-mail. .

In addition, the UMS server 6 notifies the manager in charge of the leak occurrence information and the leak occurrence position information from the calculation / analysis server 10 by voice, text, fax, and e-mail.

Accordingly, the manager in charge checks the leak occurrence information and the leak occurrence position information transmitted from the UMS server 6 to maintain the pipe network where the leak occurred.

The web server 14 authenticates a user who wants to access the water circulation management system of the watershed through the Internet, gives an access level to the authenticated user, and stores the information stored in the DB 8 according to the access level. To provide.

The manager terminal 18 is a terminal used by an administrator who manages the water circulation management system of the watershed, and transmits the change of the geographic information and / or the population information to the GIS server 12.

In this case, the manager terminal 18 may transmit the change of the geographic information and / or population information to the GIS server 12 after receiving the user authentication through the web server 14.

On the other hand, the manager terminal 18 receives the user authentication through the web server 14 and receives the change in the geographic information and / or population information from the GIS server 12.

In addition, the manager terminal 18 controls the operation of the switchgear installed in the water pipe and the sewer pipe after receiving the user authentication through the web server (14).

Accordingly, the water pipe and the sewage pipe are opened or closed according to the control signal transmitted from the collection server 4, so that the amount of water supplied to the final customer (that is, the amount of water supplied to the water pipe) and the amount of sewage discharged from the final customer (Ie, discharge amount of sewage pipe) and inflow amount into the sewage treatment plant is controlled.

In addition, the manager terminal 18 performs user authentication through the web server 14, the water quality, quantity, water pressure of the constant and sewage stored in the DB (8) in the form of charts, tables and graphs from the DB (8) , Water level, flow rate and leakage, opening and closing information of the water pipe and sewer pipe, average daily consumption of water per person, average daily water supply per person, maximum water supply per person per day, maximum water supply per hour, water demand in the area, water purification plant The amount of purified water to be purified, the power required for the purification of the raw water, the cost of the raw water purification, the chemical input required for the raw water purification, the constant use cost by the final consumer, the amount of sewage, the amount of sewage treatment, the amount of chemicals required for sewage treatment, the sewage treatment Power, location of leakage, leakage, amount of intrusion and inflow, daily maximum / minimum flow rate, daily average flow rate, inflow into the water treatment plant, outflow from the water treatment plant, flow to the drain Amount, outflow from the drainage, leakage from the water pipe, leak location of the water pipe, inflow into the water pipe, leakage from the sewage pipe, pollutant load, intrusion water entering the sewage pipe or sewage treatment plant, the Information on the amount of sewage generated at the end customer and the location of leakage in the sewer pipe is provided hourly, daily, monthly, quarterly and yearly.

Accordingly, the administrator can manage the water circulation flow in the corresponding area (the area where the water circulation management system of the watershed is installed) through the information transmitted from the DB (8).

In other words, when pollution occurs in the raw water, the manager may know whether or not pollution occurs in the raw water through the water quality information of the raw water transmitted to the manager terminal 18. By partially closing the opening and closing device of the water pipe, it is possible to appropriately control the amount of water supplied to the final consumer, thereby minimizing the water saving time (or water shortage time) due to contamination of the raw water.

In addition, since the manager receives the contamination of the raw material through the manager terminal 18, the manager can remove the pollution generated in the raw material in a short time, thereby making it possible to supply a constant water.

On the other hand, the manager terminal 18 may be provided with the error occurrence information of the field measuring instrument 2 transmitted from the UMS server 6 through the web server 14, the leakage occurrence information and leakage occurrence location information in the network. .

The user terminal 16 is a terminal used by a user in a corresponding region. When user authentication is completed through the web server 14, the constant usage amount, constant water quality, cost, and water saving from the DB 8 are stored. Information such as time (or singular time) and water saving period (or singular period) is provided.

Meanwhile, the user terminal 16 transmits a user request complaint to the DB 8 through the web server 14, and the manager terminal 18 transmits the user request complaint to the DB 8. Received from the DB (8) and provided to the administrator.

As a result, the administrator can handle the complaints requested by the user.

As such, the water circulation management system of the watershed according to the embodiment of the present invention integrates a water supply facility for supplying water from the source water to the final consumer price, and a sewage treatment facility for releasing sewage and sewage discharged from the final consumer price to the sewage treatment plant and stream. In addition to monitoring and controlling the water circulation in urban areas in real time, integrated management of water supply and sewage treatment facilities can reduce manpower and management costs for facility management.

In addition, the water circulation management system of the watershed according to an embodiment of the present invention can effectively manage the chemicals and incidental costs required for drinking water treatment because the water supply in the water purification plant can be determined by predicting the constant demand of the final consumer. In addition, since the sewage generated by each sewage treatment section is monitored in real time to control the inflow amount into the sewage treatment plant, it is possible to predict and manage the sewage treatment cost and the amount of sludge generated such as the chemical cost used for sewage treatment.

In addition, since the water circulation management system of the basin according to the embodiment of the present invention measures the amount of sewage generated by each sewage treatment section in real time, the intrusion water contained in the inflow flow rate of the sewage treatment plant by comparing the inflow amount of the sewage treatment plant and the sewage treatment plant. And by searching for the processing branches that generate the most inflow amount can not only know the contribution of the processing section, but also to select and manage the processing branches that cause the most problems intensively.

In addition, the water circulation management system of the watershed according to the embodiment of the present invention can reduce the water saving time because the water supply can be properly adjusted by supplying the final water supply to the final consumer when the water supply disruption occurs due to the pollution of the raw water In addition, since the leakage occurs in the water and sewer pipes in real time, it is easy to find the section in which the leak occurred, thereby reducing the cost caused by the leak.

In addition, the water circulation management system of the watershed according to the embodiment of the present invention calculates the population of the region in a specific year and then calculates the constant demand amount required for the region in a specific year through the constant usage by the estimated population and the end user in the region. Predictions can be used as a more scientific basis for decision-making and budget execution of water supply demands at municipalities and higher national institutions, as well as forecasting the inflow and water quality of sewage treatment plants from sewage and water quality discharged from final customers. As a result, it can be used as basic data for policy making and budget execution for sewage treatment plants.

1 is a view showing a water circulation management system of the watershed according to an embodiment of the present invention.

<Explanation of symbols for the main parts of the drawings>

2: field instrument 4: collection server

6: UMS Server 8: Database

10: operation / analysis server 12: GIS server

14 web server 16 user terminal

18: manager terminal

Claims (8)

An on-site instrument installed in raw water, water purification plant, drainage basin, sewage treatment plant, river, water pipe and sewer pipe, respectively, to measure the water quality, quantity, water pressure, water level, flow rate and leakage of water and sewage in real time; Collects data measured from the field measuring instrument in real time through a wired / wireless communication network, and if an error occurs in the measuring data transmitted from the field measuring instrument, requests the field measuring instrument to retransmit the measurement data, and corrects through filtering of abnormal data Collecting server to perform; A GIS server that provides geographic information including the area, housing type, topography, soil, pipe network, specifications of conduits, and current status of attached facilities of the area and the population information of the area; Measurement data including the water quality, quantity, water pressure, water level, flow rate and leakage, constant usage used in the final consumer, average daily usage per person using geographic information and / or population information transmitted from the GIS server, 1 Average daily water supply, maximum daily water supply per person, maximum water supply per hour, constant demand in the area, purified water to be purified at the water purification plant, power required to purify the raw water, cost of the raw water purification, chemicals necessary for the raw water purification Water input, water consumption, sewage treatment cost, chemical input for sewage treatment, power required for sewage treatment, location of leakage, leakage, intrusion and inflow, daily maximum / minimum flow, daily average flow , Inflow into the water purification plant, outflow from the water purification plant, inflow into the drainage basin, outflow from the drainage basin, leakage from the water supply pipe Discharge, location of leakage of the water pipe, inflow into the water pipe, leakage from the sewage pipe, pollution load, intrusion water intrusion into the sewage pipe or sewage treatment plant, the amount of sewage generated in the final consumer, leakage from the sewer pipe A calculation / analysis server for calculating a location; Measurement data collected by the collection server in real time, the constant amount of water used in the final customer, the average daily consumption per person transmitted from the calculation / analysis server, the average daily water supply per person, the maximum daily water supply per person, 1 Maximum water supply per capita, local water demand, purified water to be purified at the water purification plant, power required to purify the raw water, the cost of the raw water purification, chemical input required for the raw water purification, the cost of using the constant water by the final consumer, sewage and sewage treatment costs , Chemical input required for sewage treatment, power required for sewage treatment, leakage location, leakage generation amount, intrusion and inflow quantity, daily maximum / minimum flow rate, daily average flow rate, inflow into the water treatment plant, outflow from the water purification plant, the Inflow into the sump, outflow from the sump, leakage from the water pipe, leak location of the water pipe, the constant A database for storing the inflow amount into the pipe, the amount of leakage from the sewage pipe, the amount of contamination, the amount of intrusion into the sewage pipe or the sewage treatment plant, the amount of sewage generated at the final consumer price, and the location of the leakage from the sewage pipe; A UMS server that notifies the manager in charge of error occurrence information from the collection server, leak occurrence information and leak occurrence location information transmitted from the calculation / analysis server by voice, text, fax, and e-mail; A web server performing user authentication of a connecting user and granting an access level to an authenticated user; And Water management system of the watershed, characterized in that it comprises a manager terminal that receives the information from the database through the web server and provides the manager to manage the water circulation of the watershed. The method of claim 1, The calculation / analysis server receives the population information from the GIS server 12 and uses the past population information and the current population information of the region in the transmitted population information, and predicts the population growth rate of the region in the specific year. A watershed management system of a watershed, comprising calculating a population and calculating a constant demand for the region in a specific year by using the calculated estimated usage of the region and the final consumption of the final consumer. The method of claim 2, The calculation / analysis server calculates an estimated population of a corresponding region using a time series estimation method of any one of an equal order, equal order, cutting function, exponential function, logistic, and correction index as shown in Equation 1. Water circulation management system. (Equation 1) Differential Grade: y = a (bx + 1) Equivalence: y = a (1 + b) ^x Slash function: y = a (1 + b) ^x + c Exponential function: y = ax ^b + c Logistic: y = k / (1 + e ^a-bx ) Correction index: y = k-ab ^x Where y is the expected population for a particular year, a and c are the current population, b is the population growth rate, x is the number of years old, and k is the limit. The method of claim 1, The manager terminal is the water quality, quantity, water pressure, water level, flow rate and leakage of the constant and sewage from the database, the opening and closing information of the water pipe and sewer pipe, the average daily use of water, daily average water supply per person, daily per person Maximum water supply, maximum water supply per hour, constant water demand in the area, purified water to be purified in the water purification plant, power required for the purification of the raw water, the cost of the raw water purification, chemical input required for the raw water purification, constant use cost for each end user, sewage quantity , Sewage treatment cost, chemical input required for sewage treatment, power required for sewage treatment, location of leakage, leakage amount, intrusion and quantity of inflow, daily maximum / minimum flow rate, daily average flow rate, inflow into the water purification plant, Flow rate of the water supply pipe, the flow rate into the drainage basin, the flow rate from the drainage basin, the leakage flow rate from the water supply pipe, the leak occurrence position of the water supply pipe, The amount of inflow into the water supply pipe, the amount of leakage from the sewage pipe, the pollution load, the amount of intrusion into the sewage pipe or the sewage treatment plant, the amount of sewage generated at the final customer, and the location of the occurrence of leakage from the sewage pipe are provided. Water circulation management system. The method of claim 4, wherein The manager terminal transmits the change of the geographic information and / or population information to the GIS server, the GIS server updates and stores the change of the geographic information and / or population information transmitted from the manager terminal, And provide the updated geographic information and / or population information to the calculation / analysis server. The method of claim 5, After receiving the user authentication through the web server, the manager terminal controls the operation of the switchgear installed in the water pipe and the sewer pipe to regulate the water supply of the water pipe and the discharge water of the sewage pipe. Circulation management system. The method of claim 1, After receiving the user authentication through the web server is provided with the constant usage, constant water quality, cost of using the constant, water saving time, water saving period from the database, and sends the complaint of the user to the database through the web server Water basin water circulation management system further comprises a user terminal. The method of claim 7, wherein The database is a water circulation management system of the watershed, characterized in that for providing the user complaint information transmitted through the user terminal to the administrator terminal through the web server.

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