KR101185543B1 - Ubiquitous based management system forurban river and ecological lake using wide area reclaimed water network and method for managing water usage index using the same - Google Patents

Abstract

The present invention relates to a technology for improving the soundness of the urban integrated operation center and ubiquitous based urban river and ecological lake management and water circulation in the ubiquitous ecological city, and the information obtained from the quantity and water quality sensors attached to the urban and ecological lake facilities in the city. Is transmitted to the ubiquitous river and ecological lake integrated management system and analyzed to detect and evaluate the water circulation in the city (quantity, water quality) in real time, and to the ubiquitous comprehensive information center for decision support. And provide the dashedin with detailed information on water circulation, crisis (flood, drought, pollutant outflow, lake and river pollution) occurrence, and countermeasures.

Wide area water, ubiquitous based monitoring, ubiquitous river and ecological lake integrated management system

Description

UBIQUITOUS BASED MANAGEMENT SYSTEM FORURBAN RIVER AND ECOLOGICAL LAKE USING WIDE AREA RECLAIMED WATER NETWORK AND METHOD FOR MANAGING WATER USAGE INDEX USING THE SAME}

The present invention relates to a ubiquitous based monitoring and water circulation integrated management system of the appeal using wide area heavy water, such as sewage advanced treatment water, rainwater, groundwater and elution water, riverside filtration water, ubiquitous based integrated monitoring, rapid maintenance and doctor It is possible to establish a sustainable virtuous water circulation system in the city by generating alarms in real time through decisions and remote control and responding through necessary actions for alarms. In addition, based on the target water quality and multiple water sources of appeals such as urban rivers and ecological lakes, the water purification method is composed of an optional Multi Complex, and the quantitative target quantity and water supply of urban rivers and ecological lakes are controlled through ubiquitous based remote control. Water quality control can improve the health of the water cycle in the city.

Recently, diversified efforts such as reuse of sewage treatment plant, use of rainwater, and use of sewage water have been spreading as alternative water sources for improving watershed and urban water circulation and future water shortages.

For example, the expansion of advanced treatment facilities, the expansion of small-scale decentralized sewage treatment facilities, and the resetting of water quality recommendations were implemented to promote effluent reuse in sewage treatment plants, and public institutions and the government for the expansion of environmentally friendly use of rainwater and leached groundwater. It is recommended to install rainwater storage and utilization facilities in large residential complexes, and to clean up the leaching groundwater, wash water, and river maintenance water.

In addition, the use of such regional heavy water to create a city waterway, natural rivers, biotopes, etc. to provide a hydrophilic environment in the city and to use as an eco-learning place is increasing.

Therefore, to determine the efficient and rapid water purification method and proper water supply for the purpose of supplying the regional heavy water (sewage altitude treatment water, rainwater, groundwater and leaching water, riverside filtration water, etc.) to maintenance water of various lakes such as urban rivers and ecological lakes To do this, there is a need to detect the quantity and quality of the appeal, to detect pollutant inflow and pollutant sources, and to detect leakage and breakage by measuring the pressure in the water pipe.

In other words, it is necessary to develop a ubiquitous appeal management system that can monitor the quantity of water and water quality determined by various scattered water sources in real time and quickly observe, analyze, predict and predict urban river and ecological lake conditions.

The present invention detects the quantity and quality of water inflow / outflow, pollutant inflow and pollutant source using inlet / outflow using wide area water, and monitors leakage and breakage by measuring the pressure of water pipeline to issue water quantity and water quality alarms It is to provide a ubiquitous based appeal management system that can remotely control the purification facility and analyze and predict the water balance for a long time, and the water use index management method, which is a dashin water usage guide.

The ubiquitous based appeal management system utilizing the wide area heavy water of the present invention includes at least one measuring device for acquiring visual data related to water quality, quantity related data or appeal water quality for an appeal provided with water-treated heavy water; A central management server connected to the measuring device, storing and analyzing data received from the measuring device, calculating a water use index, and providing the water use index to the outside, wherein the water use index is related to the water quality. The water quality / quantity index determined by the data, or the water quality-related data and the quantity-related data, or the water quality-related data, the quantity-related data, and the image data, and the purpose of using the heavy water treated for each water quality / quantity index. It is desirable to determine in relation to the weight to be determined.
The measuring device of the present invention comprises: a water quality measuring unit for measuring the water quality related data; A quantity measuring unit for measuring the quantity related data; A transmission / reception unit configured to transmit the water quality related data and the quantity related data to the central management server; Preferably, the water quality measuring unit and the auxiliary equipment for distributing a measurement sample to the water quantity measuring unit and processing the same; and an image unit for acquiring the image data for the appeal.
It is preferable that the quantity measuring part of this invention contains a rainfall meter, a water meter, or a flow meter.
The transmission and reception unit of the present invention is preferably configured as a PLC self-wired network.
The central management server of the present invention uses the water use index (WUI, Water Usage Index) = ∑ (Q × W) (Q: water quality / quantity index of each water quality or quantity, W: weight) It is preferable that the water quality / quantity index (Q) of each water quality or water quality and quantity is a water quality or quantity value measured by the measuring device, and the weight (W) is a coefficient weighted according to the water use purpose. .
The water quality / quantity index (Q) of each water quality or quantity and quantity of the present invention is preferably specified in the range of 0 to 100 for each water quality or quantity measurement unit.
The weight of the present invention is specified as a range of 0 to 1 depending on the influence on the water quality, and it is preferable that the sum of the weights is one.
The measured values for the water quality / quantity index of the present invention are suspended solids (SS), acidity (pH), water temperature (Temp), dissolved oxygen (DO), chlorophyll (Chl-a), chemical oxygen demand (COD), total organic carbon. Small amount (TOC), turbidity, total nitrogen (TN), total phosphorus (TP), quantity or flow rate (FLW), hydrogen ion concentration (PHY), electrical conductivity (CON), suspended solids (SUS), biochemical It is preferably composed of oxygen demand (BOD), chlorine (CLR) or chromaticity (COL).
The central management server of the present invention comprises a unit system server for processing data transmitted from the measuring device; An integrated processing server that receives data from the unit system server and stores and processes the data according to characteristics; It is preferred that the central processing server for analyzing the data stored by the integrated processing server to calculate the water use index; and a transmission and reception server for transmitting the water use index calculated by the central processing server to the outside.
The central management server of the present invention preferably transmits the water use index to a general web user, an external organization or an electronic billboard through the Internet, and delivers the water use index to a mobile phone user through a mobile communication network.
Water balance management method using the integrated water balance management system of the appeal using the wide area heavy water of the present invention is a measuring device for measuring a variety of data for the water is provided water treatment, and processing the data received from the measuring device A management method using the system comprising a central management server, comprising: a data acquisition step of acquiring the water quality related data, the quantity related data or the image data by the measuring device; A water use index calculation step of calculating a water use index through the obtained data; and an analysis step of analyzing the calculated water use index; and a water use index providing step of providing the water use index and an analysis result to the outside; It is preferable to include.
The water use index calculation step of the present invention using WQI (Water Usage Index) = ∑ (R × Q × W) (R: measured values for each water quality / quantity index, Q: unit correction coefficient, W: weight) The water use index is calculated, and the unit correction coefficient Q is a coefficient for correcting each water quality / quantity index in reference units, and the weight W is preferably a coefficient weighted according to the influence on the water quality. .
In the analysis step of the present invention, it is preferable to classify the water use index or the quantity / water quality measurement value by period and place, and calculate the pollution degree change and the water quality change amount for each search condition according to the classification result.
In the providing step of the present invention, it is preferable to provide the amount of change to the measured water quality or quantity value for a predetermined time period by division.
In the providing step of the present invention, it is preferable to provide a water usage guide for each water quality grade according to the water use index and the analysis result.

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According to the present invention, the water circulation in the city is integrated and managed, and in particular, the quantity and quantity of urban rivers and ecological lakes using regional heavy water (sewage treatment, rainwater, groundwater, underground facility runoff, riverside filtration, etc.) Provides information to operators, field workers, related organizations and citizens through ubiquitous monitoring of water quality status, pollutant inflow and pollutant detection, quantitative and water quality alarms, control of water purification facilities, and long-term water balance analysis and prediction It can be utilized by linking the ubiquitous water circulation integrated management system and the city integrated operation center.

In addition, the present invention uses the ubiquitous infrastructure installed in the city, and time and effort to create information compared to the existing method (analysis after field sampling) when evaluating the health and quantity of urban rivers and ecological lake maintenance water in real time It is possible to establish a sustainable virtuous water circulation system in the city by generating and responding to alarms in real time through ubiquitous based integrated monitoring, rapid maintenance and decision making, and remote control. Therefore, the city integrated operation center can quickly observe, analyze, predict, and control the urban streams and ecological lakes, and establish a water circulation system that can prevent disasters by reducing maintenance costs and significantly reducing decision-making time. have.

In addition, it is possible to ultimately provide important evidence on the direction of administrative and policy support through various information on the water use index, and to provide the water use guide to the general public using various appeals, thereby maximizing the waterside space and using the waterside space. Safety can be extended.

Hereinafter, with reference to the accompanying drawings, a preferred embodiment of the ubiquitous appeal management system and the water use index management method using the same according to the present invention will be described in more detail.

1 to 16 show a preferred embodiment of the ubiquitous appeal management system utilizing the wide-area heavy water according to the present invention and a water use index management method using the same.

Figure 1 shows in which stage the ubiquitous appeal management system according to the present invention is applied in the overall water circulation system.

The heavy water collected through the sewage treatment plant (1), natural stormwater storage facility (3), and stormwater storage facility (5) is transferred to the heavy water treatment facility (10) via the regional water treatment system (7), or other artificial It is supplied to the river (9).

Then, the water that has been treated by the heavy water treatment facility 10 is supplied to various lakes, such as urban ecological rivers 13 and ecological lakes 15, and used as water, and the water supplied to the various lakes flows back into the river. Or it is collected by the heavy water treatment plant 10 and recycled to the facility.

The ubiquitous appeal management system according to the present invention is to provide a variety of information on the water flowing into the various appeal by measuring and analyzing various quantities / water quality, etc. for the water is completed by the heavy water treatment facility (10). .

As shown in FIG. 2, the integrated water balance management system according to the present invention includes a plurality of measuring devices installed in various appeals, and a central management server for integrated management of water-use index-related data measured from the measuring devices. It is composed.

The measuring device 100 transmits information such as water quality items, quantity, water level, water temperature, and the like of various appeals provided with water-treated wide area heavy water to the central management server 200 by using a sensor. The measuring device 100 is installed in the measuring station of the various appeal, the measuring device 100 and the central management server 200 may be connected to the wired or wireless network, but preferably connected by a PLC-based self-wired network. Do.

The measuring device 100 includes a quantity / water quality measuring unit 110 for measuring quantity / water quality. The water quantity / water quality measuring unit 110 includes various water quality items in the appeal (floating matter (SS), acidity (pH), water temperature (Temp), dissolved oxygen (DO), chlorophyll (Chl-a), chemical oxygen demand (COD)) ), Total Organic Carbon (TOC), Turbidity, Total Nitrogen (TN), Total Phosphorus (TP), Quantity or Flow Rate (FLW), Hydrogen Ion Concentration (PHY), Electrical Conductivity (CON), Suspended Substance (SUS) ), Biochemical oxygen demand (BOD), chlorine (CLR) and chromaticity (COL, etc.) water quality measurement unit 111, and various quantity items such as the flow rate or quantity (Flow), water level or precipitation of the appeal It includes a quantity measuring unit 113 for measuring.

The water quality measuring unit 111 may be configured as a multiprobe water quality sensor, and the water quality measuring unit 113 may include a rain gauge, a water level meter, and a flow meter.

The measuring device 100 transmits the quantity / water quality data measured by the quantity / water quality measuring unit 110 to the central management server 200 and receives the control signal transmitted from the central management server 200. And a transmission / reception unit 120. The transmission / reception unit 120 may be configured as a data logger to transmit / receive data.

In addition, the measuring device 100 includes an auxiliary device 130 for collecting and dispensing a sample. As shown in FIG. 3, the accessory equipment 130 includes a water collecting box 131 for collecting water, and the water collected by the water collecting box 131 moves to the distribution box 133.

Then, the water moved to the distribution box 133 is moved to the various water quality measuring sensors constituting the water quality measuring unit 111 is the water quality for the sample is measured. 4 shows water quality related data measured for each time zone by the water quality measuring unit 111, and details of water quality related data are shown in detail in FIG. 5.

The measuring device 100 may further include an imaging unit 140 for observing each measuring station and the appeal where the measuring device 100 is installed. The imaging unit 140 serves to determine the degree of turbidity or inclusion of foreign matter that is visually confirmed.

The quantity / water quality data measured by the measuring device 100 is transmitted to the central management server 200 of the comprehensive information center. The central management server 200 stores and analyzes the quantity / water quality related data measured by the measuring device 100, and calculates the related information for the water use index through the analyzed data, and the related agencies and It transmits information to users.

The central management server 200 includes a unit system server 210 connected to the measuring device 100 installed in each measuring station. In addition, the central management server 200 includes an integrated processing server 220 for storing and managing various data provided through the unit system server 210.

The integrated processing server 220 processes and manages geographic information, video information, various water quality related information, and information related to communication. The integrated processing server 220 may include an integrated WEB / WAS server, an integrated GIS server, an integrated storage server, an integrated video unit server, an integrated UMS server, and an integrated operating DB server.

Various data stored by the integrated processing server 220 are analyzed and processed by the central processing server 230. The central processing server 230 analyzes various quantity / water quality data measured by the measuring device 100, calculates a water use index, and delivers it to a web user or a city citizen.

The central processing server 230 provides a water use index based on the quantity / water quality measurement data measured by the measuring device 100. The water use index is the sum of the product of each water quality / quantity index (Q) and the weight (W), and the absolute value of the numerical value for the water quality and the numerical value for the quantity to a numerical value that can be compared with each other, the purpose of using water By multiplying the weights determined by each other means that it is converted into a value for determining the utilization value of the global weight.
As shown in Table 2, when the water quality / quantity index (Q) and the weight (W) of each measured water quality or water quality and quantity are determined, a parameter index is calculated based on the values calculated for each water quality and The total is calculated to calculate the water use index (WUI).
The method of calculating the water use index by the central processing server 230 is shown in Equation 1 below.

Water Usage Index (WUI) = ∑ (Q × W)

(Q: water quality / quantity index of each water quality or water quality and quantity measured, W: weight)

In Equation 1, Q is a water quality / quantity index of each measured water quality or quantity and quantity, suspended matter (SS), acidity (pH), water temperature (Temp), dissolved oxygen (DO), chlorophyll (Chl-a) , Chemical oxygen demand (COD), total organic carbon (TOC), turbidity, total nitrogen (TN), total phosphorus (TP), quantity or flow rate (FLW), hydrogen ion concentration (PHY), electrical conductivity (CON ), Suspended solids amount (SUS), biochemical oxygen demand (BOD), chlorine (CLR), chromaticity (COL), quantity or flow rate.

In addition, in Equation 1, Q is a water quality / quantity index of each water quality or water quality and quantity measured, and the Q value of each water quality or water quality / quantity is defined in Table 1 below.

As shown in Table 1, the water quality / quantity index may consist only of measurement factors relating to water quality, only measurement factors relating to water quality and quantity, or may be comprised of measurement factors relating to water quality, quantity, and image. . Measurement factors related to images are not listed in Tables 1 and 2, but refer to measurement factors related to water quality such as turbidity that can be visually confirmed. Then, each of the water quality / quantity indexes are corrected by being divided into permissible, slightly good, moderate, bad, and extremely bad.

W is a weight, and the weight can be adjusted for each water use. As shown in Table 2 below, the weight W is specified as any one of 0 to 1 in consideration of the water use purpose, and the sum of the weights should be 1.

As shown in Table 2, when the water quality / quantity index (Q) and the weight (W) of each measured water quality or water quality and quantity are determined, a parameter index is calculated by the values calculated for each water quality / quantity. The total sum is calculated to calculate the water use index (WUI).

When the water use index (WUI) is calculated, the water quality / quantity level is set for each value, and based on this, the water use guide can be presented as shown in Table 3 below.

Each data calculated by the central processing server 230 is transmitted to the information requestor such as an Internet accessor or a mobile user, an external agency, or an information board by the transmission / reception server 240. Accordingly, the transmission and reception server 240 includes both a mobile communication network such as CDMA, an Internet network or its own PLC wired network, and other frequency wireless networks.

In addition, the central processing server 230 obtains statistics of water quality, quantity, and water level by process, equipment, and time in real time, and analyzes the trend of water quality, quantity, and water level through the simulation, and simulates long-term water balance through simulation. Predict changes in water quality, quantity, and level.

In addition, the central processing server 230 warns (alarms) when an error occurs in comparison with the water quality / quantity standard of the ecological maintenance water, and informs the water quality alarm for water degradation, toxic substances inflow, pathogenic microorganisms detection, ecological river / The short and long term water quality of the lake can be predicted, so it is possible to analyze the short and long term water balance of ecological rivers and lakes.

In addition, the central processing server 230 may detect and provide a leak due to pipe breakage through a pressure difference in the pipe line, and may also notify the water level according to the quantity change.

Hereinafter, the ubiquitous appeal management system using the wide-area heavy water according to the present invention having the configuration as described above and the water use index management method using the same will be described in detail.

First, a step of measuring the water quality and quantity of the measuring station by the measuring device 100 and taking an image by the imaging unit 140 is performed. In addition, the water balance data measured by the water quality measuring unit 111 and the water quantity measuring unit 113 of the measuring device 100 and the image data photographed by the image unit 140 are transmitted and received by the transmission unit 120 and the self. The wired network is transmitted in real time to the central management server 200.

When data is transmitted to the central management server 200, as shown in FIG. 6, the general information center manages the data using the central management server 200 and provides information through an analysis and prediction process.

As shown, various water balance related data and image data measured by the measuring device 100 is monitored and transferred to the integrated processing server 220 through the unit system server 210. The integrated processing server 220 classifies, stores and manages the received data by characteristics.

The central processing server 230 analyzes the information stored in the integrated processing server 220 for each water quality measurement element, for each quantity measurement element, and for each image information to derive a result. For example, as described above, the central processing server 230 calculates a water use index (WUI) by multiplying the measured values for each water quality / quantity index by a unit correction factor and a weight.

The central processing server 230 prepares average data, period data, place data, pollution degree change, water quality change statistics and treatment process DB based on the calculated water use index and image data, and changes in water pollution by search conditions. Analyze the trend.

As described above, when the water quality information is analyzed by the central processing server 230, the comprehensive information center sets a process improvement direction for each sewage treatment plant and heavy water treatment system, and establishes an administrative policy based on this. Can be.

Then, when the water quality information and various data analysis is completed by the central processing server 230, these results are provided to related organizations and information users through the transmission and reception server 240.

Information provision can be divided into a method of providing to an internally linked system and a method of providing to an externally linked institution. Internal linkage service can be provided through a billboard or kiosk to provide the information center itself with water quality information.

In addition, external linkage services may be provided to local water circulation research organizations such as health and environmental researchers, local governments and heavy water treatment agencies.

An example of providing a service of a comprehensive information center using the central processing server 230 is illustrated in FIG. 7. As shown, the central processing server 230 may provide the related organizations and information users with the final water use index calculated by remotely monitoring and analyzing and evaluating relevant information measured in real time automatically.

In addition, the central processing server 230 may issue a water pollution alarm according to the measured water quality information, and provide information to perform a water pollution control operation accordingly.

In addition, it is possible to ultimately provide important evidence on the direction of administrative and policy support through various information on appeals, and provide water usage guides to the general public using various appeals to maximize the waterfront space and the safety of waterfront space use. You can zoom in.

An example of a program for managing quantity / water quality information provided by the central processing server 230 is illustrated in FIGS. 8 to 16.

8 is a login screen for using the ubiquitous appeal management system. 9 is a screen for providing a value of an average value of the previous day to be disclosed to information requesters as a water use index (WUI).

FIG. 10 is a historical trend screen created by the central processing server 230, and is a screen in which a change amount of a day's water quality value is set hourly and minutely. This allows you to look at the amount of change in quantity / water quality throughout the day.

In addition, FIG. 11 is a screen showing warning, warning, and the like by indicating the water quality-related numerical value measured in order to grasp the state of the water use index compared with the reference value.

12 is a screen for setting the water quality / quantity index (Q) and the weight (W) of each water quality for calculating the water use index. Through this, unit correction coefficients and weights can be set for each water quality index.

FIG. 13 is a screen for setting a guide that can use water by dividing the water use index calculated by the central processing server 230 by range and calculating a grade thereof. Each water quality level can be set by directly filling in the available water usage guide.

14 is a screen for setting a range of grades calculated for each water quality grade.

15 is a screen for setting a range of water quality / quantity index of each water quality or water quality and quantity to be calculated for each water quality grade.

16 is a graph showing the data finally calculated by the central processing server 230.

In the scope of the basic technical spirit of the present invention, many modifications are possible to those skilled in the art, and the scope of the present invention should be interpreted based on the claims which will be described later. .

1 is a conceptual diagram illustrating a water treatment circulation process to which a ubiquitous management system of an appeal utilizing wide area heavy water according to the present invention is applied.

Figure 2 is a block diagram showing a preferred embodiment of the ubiquitous management system of the appeal utilizing a wide area heavy water according to the present invention.

Figure 3 is a block diagram showing the configuration of the measuring device of the ubiquitous management system of the appeal utilizing the wide area heavy water according to the present invention.

Figure 4 is a graph showing the measurement results measured by the measuring device of the ubiquitous management system of the appeal utilizing the wide area water according to the present invention.

5 is a screen showing various numerical values by the graph of FIG.

Figure 6 is a relationship showing the relationship of processing and providing data by the ubiquitous management system of the appeal utilizing the wide area water according to the present invention.

Figure 7 is a conceptual diagram showing the contents of the service provided by the water use index management method using the ubiquitous management system of the appeal utilizing the wide area heavy water according to the present invention.

8 to 16 are program screens for implementing a water use index management method using the ubiquitous management system of the appeal utilizing the wide area heavy water according to the present invention.

Description of the Related Art [0002]

100: measuring device 111: water quality measuring unit

113: quantity measuring unit 120: transceiver

130: additional equipment 140: video unit

200: central management server 210: unit system server

220: integrated processing server 230: central processing server

240: transmission and reception server

Claims (15)

At least one measuring device for acquiring water quality-related data, quantity-related data, or image data for visually confirming the quality of the appeal water for an appeal provided with water-treated heavy water; And a central management server connected to the measuring device, storing and analyzing data received from the measuring device, calculating a water use index, and providing the water use index to the outside. The water use index is Use of water quality / quantity index determined by the water quality-related data, the water quality-related data and the quantity-related data, or the water quality-related data, the quantity-related data and the image data, and the water-treated heavy water for each water quality / quantity index Determined in relation to the weight determined by purpose. Ubiquitous management system of appeal using wide area water. The method of claim 1, The measuring device A water quality measuring unit for measuring the water quality related data; A quantity measuring unit for measuring the quantity related data; A transmission / reception unit configured to transmit the water quality related data and the quantity related data to the central management server; Subsidiary equipment for distributing and processing measurement samples in the water quality measurement unit and the water quantity measurement unit; And An imaging unit for acquiring image data for the appeal. Ubiquitous management system of appeal using wide area water. 3. The method of claim 2, The quantity measuring unit Including rainfall meters, water meters or flow meters Ubiquitous management system of appeal using wide area water. 3. The method of claim 2, The transmitting and receiving unit PLC self-contained wired network Ubiquitous management system of appeal using wide area water. The method of claim 1, The central management server Water Usage Index (WUI) = ∑ (Q × W) (Q: water quality / quantity index of each water quality or quantity, W: weight) To calculate the water use index, The water quality / quantity index (Q) of each water quality or quantity and quantity is the water quality or quantity value measured by the measuring device. The weight (W) is a coefficient weighted according to the use of water Ubiquitous management system of appeal using wide area water. The method of claim 5, The water quality / quantity index (Q) of each water quality or quantity Specified in the range of 0 to 100 for each water quality or quantity unit of measure Ubiquitous management system of appeal using wide area water. The method of claim 5, The weight (W) is specified in the range of 0 to 1 according to the effect on the water quality, the total of the weight is 1 Ubiquitous management system of appeal using wide area water. The method of claim 5, The measured value for the water quality / quantity index Suspended solids (SS), acidity (pH), water temperature (Temp), dissolved oxygen (DO), chlorophyll (Chl-a), chemical oxygen demand (COD), total organic carbon (TOC), turbidity, total nitrogen (TN), total phosphorus (TP), quantity or flow rate (FLW), hydrogen ion concentration (PHY), electrical conductivity (CON), suspended solids (SUS), biochemical oxygen demand (BOD), chlorine (CLR) or chromaticity Composed of (COL) Ubiquitous management system of appeal using wide area water. The method of claim 1, The central management server A unit system server for processing data transmitted from the measuring device; An integrated processing server that receives data from the unit system server and stores and processes the data according to characteristics; A central processing server analyzing the data stored by the integrated processing server to calculate the water use index; and And a transmission and reception server configured to transfer the water use index calculated by the central processing server to the outside. Ubiquitous management system of appeal using wide area water. The method of claim 1, The central management server Delivering the water use index to general web users, external organizations or billboards through the Internet, Delivering the water use index to mobile phone users through a mobile communication network Ubiquitous management system of appeal using wide area water. A system according to any one of claims 1 to 10, comprising a measuring device for measuring various data for an appeal provided with water-treated heavy water, and a central management server for processing data received from the measuring device. In the management method to use, A data acquiring step of acquiring the water quality related data, the quantity related data or the image data by the measuring device; A water use index calculation step of calculating a water use index through the obtained data; and An analysis step of analyzing the calculated water use index; And Comprising a water use index providing step of providing the water use index and analysis results to the outside Water balance management method using integrated water balance management system of appeal using wide area water. 12. The method of claim 11, The water use index calculation step WQI (Water Usage Index) = ∑ (R × Q × W) (R: measured value for each water quality / quantity index, Q: unit correction factor, W: weight) To calculate the water use index, The unit correction coefficient Q is a coefficient for correcting each water quality / quantity index in reference units, The weight (W) is a coefficient weighted according to the effect on the water quality Water balance management method using integrated water balance management system of appeal using wide area water. 12. The method of claim 11, The analysis step The water use index or the quantity / water quality measurement values are classified by period and place, The amount of change in pollution level and the amount of change in water quality are calculated according to the classification results. Water balance management method using integrated water balance management system of appeal using wide area water. 14. The method of claim 13, The providing step Provides the amount of change in the measured water quality or quantity over time Water balance management method using integrated water balance management system of appeal using wide area water. 12. The method of claim 11, The providing step Providing a water use guide available for each water quality grade according to the water use index and the analysis result Water balance management method using integrated water balance management system of appeal using wide area water.

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