KR101554981B1 - Water supply pipe network management server, system for water supply pipe network management and pipe network management method using the same - Google Patents

Abstract

The present invention relates to a water supply network management system block divided into unit blocks. The water supply network management system includes a measuring unit installed in each of the blocks of a water supply network to measure the flux of top water by block; a water supply network management sever obtaining and storing flux data, measured from the flux of the top water, from the measuring unit, and providing a leakage warning when a difference between a real time flux data value and the stored flux data value exceeds an allowance; and a user terminal requesting the registration of a user-defined pattern for a specific block by accessing the water supply network management server, and outputting the leakage warning. The water supply network management server includes a step of generating a flux pattern according to time of the specific block by using the flux data, stored in the specific block corresponding to a period included in the request for the registration of the user-defined pattern; a step of registering the flux pattern as the user-defined pattern; and a step of providing the leakage warning when a difference between the real time flux data value about the specific value and the flux data value on the user-defined pattern corresponding to the real time flux data value exceeds the allowance.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a water supply pipe network management server, a water supply pipe network management system, and a pipe network management method using the water pipe network management server,

The present invention relates to a water supply pipe network management server, a water supply pipe network management system, and a pipe network management method using the same. More particularly, the present invention relates to a water supply pipe network management server, a water supply pipe network management system, ≪ / RTI >

The tap water that we use at home is supplied to each household (consumer) from the water source through the water purification plant and the reservoir. At this time, it is very difficult to maintain and manage proper water quality and pipe network through the pipe network which is tangled like a web from the water purification plant to the consumer.

Accordingly, a project is currently underway to optimize the management of the water supply network and block the water supply network in order to improve the flow rate (the ratio of the water collected from the water purification plant to the rate of water revenue).

For example, in the water pipe blocking business, the large blocks divided by the water supply system of the water purification plant are divided into small blocks of 2000 to 5000 water supply sizes, and the blocks are divided into small blocks of 500 to 1000 water supply sizes, It is possible to maintain and manage the network more systematically and efficiently by real-time monitoring and analysis of water quantity, water quality, and water pressure of each block by the checkerboard large, medium and small blocks.

Particularly, as the water supply network is blocked and remotely maintained, there is no need to arrange the functional personnel in the field, so that it is economical in terms of cost, and it is possible to track the whereabouts of the flow, , Total use flow rate, individual use flow rate by house, etc., and it is possible to charge more fairly.

Regarding this, in Patent Registration No. 10-1090360 and No. 10-1205103, data for each block or system for monitoring each block is collected to monitor water leakage or water quality, and a countermeasure is automatically provided in case of an accident Is disclosed.

Particularly, with respect to leakage, there has been disclosed a method of real-time monitoring of flow rate or a method of analyzing trend of real-time flow data to predict leakage, etc. However, the flow pattern of a block to be monitored by a user is defined And there is no mention of a method of using this to provide leak alarms.

An object of the present invention is to provide a water supply pipe network management server that provides a leakage alarm by defining a flow pattern of a specific block using a flow data of each block accumulated in a blocked water supply pipe network and comparing the flow pattern with a real time flow pattern of the corresponding block, A water supply network management system and a network management method using the same.

According to an aspect of the present invention, there is provided a system for managing a pipe network of a water supply system, the water supply system comprising: The flow rate data is obtained by measuring the flow rate of the constant water from the measuring means and comparing the real time flow rate data value with the stored flow rate data value. When the difference value exceeds the allowable range, And a user terminal connected to the network management server for requesting registration of a user defined pattern for a specific block and outputting the leak alarm, wherein the network management server comprises: Corresponding to the designated period included in the user-defined pattern registration request among the stored flow data And the flow rate data on the user-defined pattern corresponding to the real-time flow rate data value is stored in the user-defined pattern, The leakage alarm is provided when the difference value of the value exceeds the allowable range.

In addition, the network management server may further include, when an exception pattern including a condition for not providing the leak alarm is registered together with the user definition pattern, if the condition is satisfied, even if the difference value exceeds the allowable range, Leakage alarm may not be provided.

In addition, the condition included in the exception pattern may include at least one of an exception period, an exception permission count, and an exception permission range.

Also, the exception pattern may be registered through the user terminal according to the exception event generation information generated in the specific block.

The exception pattern may be automatically registered on the network management server under the same conditions as the above-mentioned conditions for each period in which the exception event occurs when the exception event is an occurrence periodically.

Also, the network management server provides the registered user defined pattern and the real time flow rate data to the user terminal, and the user terminal graphically displays the user defined pattern and the real time flow rate data provided from the network management server Can be displayed.

In another aspect of the present invention, there is provided a method of managing a pipe network using a blocked pipe network management system, comprising the steps of: measuring a flow rate of a constant water for each block of the water supply pipe network; Storing a flow rate of the measured constant as flow data for each block; requesting registration of a user-defined pattern for a specific block among the blocks; Generating a flow pattern according to time using the flow data corresponding to the specified period and registering the generated flow pattern with the user defined pattern; and comparing the real time flow data value and the real time flow data value If the difference value of the flow data value on the user-defined pattern exceeds the allowable range, It includes the step of providing the information.

The method may further include the step of registering an exception pattern including a condition that does not provide the leakage alarm, and when the condition is satisfied, the leakage alarm may not be provided even when the difference value exceeds the allowable range .

In addition, the condition included in the exception pattern may include at least one of an exception period, an exception permission count, and an exception permission range.

Meanwhile, a pipe network management server of the waterworks blocked by unit blocks according to another embodiment of the present invention is installed in each block of the water supply pipe network, and the flow rate of water (water) A database unit for receiving and storing the flow rate data from the collecting unit, a database unit for storing the flow rate data from the collecting unit, Generates a flow pattern according to time using flow data corresponding to a designation period included in the user defined pattern registration request among the flow data for the specific block stored in the database, A user-defined pattern registration unit for registering in a user-defined pattern, and a real- If the amount of data values and the difference value of the flow rate data value on the user-defined pattern corresponding to the real-time flow rate data value to exceed the allowable range and a leak alarm unit for providing the leak alarm to the user terminal.

In addition, the user-defined pattern register further registers an exception pattern including a condition that does not provide the leakage alarm, and when the condition is satisfied, even if the difference value exceeds the allowable range, Leakage alarm may not be provided.

In addition, the condition included in the exception pattern may include at least one of an exception period, an exception permission count, and an exception permission range.

According to various embodiments as described above, it is possible to monitor leakage generated in the pipe network by using a user-defined pattern based on the flow data accumulated for each block, and to generate unnecessary alarms when the real time flow data is out of the allowable range under normal circumstances . As a result, more efficient network management becomes possible.

1 is a block diagram illustrating a network management system according to an embodiment of the present invention.
2A to 2C are views illustrating an example of a UI on a web page provided by a network management server according to an embodiment of the present invention.
Figure 3 is an illustration of flow data and user defined patterns for a particular block.
Figure 4 is an illustration of an annual user defined pattern.
5 is a graph showing real-time flow data of a specific block and flow data on a user-defined pattern corresponding thereto.
FIG. 6 is a flowchart illustrating a network management method according to an embodiment of the present invention.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings. In the following description of the prior art and the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention unnecessarily obscure. The following terms are defined in consideration of functions in the present invention, and this may vary depending on the intentions or relationships of users, operators, and the like. Therefore, the definition should be based on the contents throughout this specification.

1 shows a network management system according to an embodiment of the present invention. Referring to FIG. 1, in a pipe network management system of a water supply system blocked by unit blocks, a pipe network management system 10 according to an embodiment of the present invention includes a measurement unit 200, (100) and a user terminal (300). Here, the unit block may be any of a large block, a medium block, and a small block.

The measuring means 200 can measure the flow rate, water pressure and water quality of the constant water. Specifically, the measuring unit 200 includes a pressure gauge 210 installed in each block constituting the pipe network to measure a constant water pressure on a block-by-block basis, a flow meter 220 for measuring a flow rate, a water quality meter 230 for measuring water quality, . ≪ / RTI >

Measurement data on the water pressure, flow rate, and water quality of the constant water measured by the measurement means 200 can be provided to the network management server 100 through the wired and wireless communication network 1. Specifically, the hydraulic pressure, flow rate, and water quality data for each block in the water supply network measured by the measurement unit 200 are periodically transmitted to the network management server 100 at regular intervals or when there is a request from the network management server 100 Lt; / RTI > The wired and wireless communication network may be a mobile communication network including a WCDMA network, a KT exclusive line, and the like, but is not limited thereto.

The network management server 100 can store various measurement data obtained from the measurement unit 200 for each block and can provide various services to the user terminal 300 by processing the measurement data. At this time, the user terminal 300 accesses the network management server 100 through the Internet network 2 and can use various services provided by the network management server 100. Here, the user terminal 300 may be a desktop PC, a notebook, a workstation, and the like, but is not limited thereto, and may be various mobile devices including a smart phone.

Specifically, the network management server 100 may provide a pattern management service for patterning and managing flow data stored for each block. Here, the pattern management service registers the flow pattern for a specific block in a user-defined pattern, monitors the flow rate of the block based on the registered user-defined pattern, judges in real time whether the block is leaking, A service that can provide alarms.

In order to provide the pattern management service, the network management server 100 can acquire and store the flow rate data measuring the flow rate of the constant from the measurement means 200. [ Specifically, the network management server 100 may store the flow rate data of each block in the water supply pipe network obtained from the measurement unit 200, for each block, by matching the measured time.

If the user terminal 300 requests the user terminal 300 to register a user-defined pattern, the network management server 100 may use the stored flow data corresponding to the designation period included in the request, And the generated flow pattern can be registered in a user defined pattern.

Here, the user-defined pattern means a flow pattern defined by the user as a pattern that is a reference of the flow rate variation of a specific block to be managed by the user. The flow data of any block in the water supply pipe network is a constant pattern The flow rate data stored in the customer management server 100 can be used as a reference for detecting the leakage of a specific block.

Specifically, when a period is designated for a specific block within the network through the user terminal 300 and a user-defined pattern registration is requested, the network management server 100 stores the flow data for the specified period of the specific block among the stored flow data A flow pattern according to time can be generated and registered as a user defined pattern. At this time, the designated period may be set to a specific date.

For example, when it is requested to register the flow data of October 10, 2010 for the small block A in a user-defined pattern, the network management server 100 stores the flow data stored in the small block A on October 10, 2010 The flow pattern can be generated using the date flow data and registered as a user defined pattern.

On the other hand, the user-defined pattern registration request may include information on the allowable range. Here, the allowable range is a value set by the user as a limit of the difference value between the real-time flow data value and the flow data value on the user-defined pattern corresponding to the specific block. For example, the user can access a web page provided by the network management server 100 through the user terminal 300 and register a user defined pattern by setting a period. At this time, the allowable range can also be set.

In addition, the user-defined pattern registration request may include information on the application period. Specifically, the application period is a period during which the registered user defined pattern is to be applied, and the application period may also be set when the user defined pattern is registered through the user terminal 300. [ In the case of the above example, if the application period is set from November 1, 2014 to November 30, 2014, the flow pattern of October 10, 2010 registered in the custom pattern will be applied to the same application period.

On the other hand, the application period may include a plurality of intermittent or continuous periods, and a different user defined pattern may be applied to each period. For example, if three user-defined patterns, such as X, Y, and Z, are registered, the X user-defined pattern is from January to April, the Y user-defined pattern is from May to September, The pattern may be applied in October or December, respectively.

Accordingly, the network management server 100 compares the real-time flow rate data value for a specific block with the flow rate data value on the corresponding user-defined pattern and provides a leakage alarm when the difference value exceeds the allowable range.

Specifically, as described above, the network management server 100 can acquire the flow rate data for each block in the water supply pipe network from the measuring means 200 in real time, so that the real time flow rate The data value can be obtained and compared with the corresponding flow data value on the user-defined pattern to calculate the difference value.

At this time, the flow data value on the user-defined pattern corresponding to the real-time flow data value means that the flow data of October 10, 2010 for the small block A is registered in a user-defined pattern and the application period is 2014 If the flow data value of the small block A is 400 as of 10 am on Nov. 25, 2014, the real time flow data value of the small block A becomes 400 , And the corresponding flow data value on the user-defined pattern is the flow data value of the small block A at 10:00 am on October 10, 2010.

On the other hand, the network management server 100 can provide a leakage alarm to the user terminal 300 when the calculated difference value exceeds the allowable range. That is, in the above example, if the allowable range of the user-defined pattern registration for the small block A is set to 100, and the flow data value at 10:00 am on October 10, 2010 was 250, The pipe network management server 100 provides a leak alarm to the user terminal 100 since the difference value 250 of 150 corresponding to the flow data value on the pattern exceeds the allowable range 100. [

However, the present invention is not limited to this. For example, even if the real-time flow rate data value is 100 in the above example, the flow rate data values on the user- The network management server 100 provides the leakage alarm to the user terminal 300. In this case,

This can be estimated not only when the real-time flow data value of the small block A exceeds the allowable range based on the corresponding flow data value on the user-defined pattern, but also when there is a leakage value even when the value is less than the allowable range to be. Meanwhile, according to the embodiment, the network management server 100 can provide different leakage alarms by distinguishing the two cases.

On the other hand, when registering a user-defined pattern, the network management server 100 may register an exception pattern including a condition that does not provide leak alarm together with the user-defined pattern.

As described above, when the difference value between the real-time flow rate data value of the specific block and the flow rate data value on the user-defined pattern corresponding thereto exceeds the allowable range, it can be estimated that there is a leak in the specific block. 100 provide a leak alarm to the user terminal 300. [

However, in some cases, even under normal circumstances, the difference value may exceed the allowable range. For example, even in large apartment complexes located within a particular block, if there is a reservoir or there is a repair for the pipe network located within a particular block, the difference value may be beyond the tolerance.

In this way, when a planned exception event occurs, not a leakage due to actual pipe network breakage or the like, it is not preferable that the leakage alarm is provided because the difference value exceeds the allowable range.

Accordingly, when registering a user-defined pattern through the user terminal 300, the user can register the exception pattern together with consideration of the occurrence of the exception event. At this time, the exception pattern may include at least one of an exception period, an exception permission count, and an exception permission range.

Specifically, the user of the user terminal 300 accesses the network management server 100 through the user terminal 300 to receive exception event information including at least one condition, Can be registered together in a custom pattern. At this time, the exception event occurrence information can be obtained by the user through telephone or mail, but is not limited thereto.

When the exception pattern is registered, the network management server 100 determines whether the condition included in the exception pattern is satisfied even when the difference exceeds the allowable range. If the condition is satisfied, The leakage alarm is not provided.

For example, in the example above, if the apartment complex located in Soblock A is scheduled to receive apartment water tanks between 9 am and 11 am on November 25, 2014, the user who obtained information about the occurrence of this exception event An exception pattern including a condition for changing the exception period from 9:00 am to 11:00 am on November 25, 2014 may be registered together with the user definition pattern.

Accordingly, a leakage alarm is not provided to the user terminal 300 even if the difference value between the real-time flow rate data value and the flow rate data value on the user-defined pattern exceeds the allowable range during the corresponding time. If the difference value exceeds the allowable range beyond the exceptional period, it is a matter of course that a leakage alarm is provided to the user terminal 300.

The condition included in the exception pattern may further include an exception permission count or an exception permission range. If the condition that the exception permission count is 1 and the exception permission range is 300 is further included in the above example, the exception If the difference value exceeds the allowable range 100 more than 2 times or exceeds the exception allowable range 300 even if the difference value is within 9:00 am to 11:00 am on November 25, Leakage alarm will be provided.

On the other hand, when the exception event related to the registered exception pattern is an event that occurs regularly, the network management server 100 stores the exception pattern in the same condition as the condition included in the registered exception pattern, Can be registered automatically.

For example, in the above example, if the apartment water tank receiving event in the apartment complex located in the small block A occurs at the same time on the same quarter, the network management server 100 determines that the user Even if you register an exception pattern that includes an exception period of 9:00 AM to 11:00 AM, the next time you receive an apartment water tank from 9:00 AM to 11:00 PM on February 25, 2015, and 9:00 AM on May 25 11:00 am, and 25:00 am from 9:00 am to 11:00 am can be automatically registered as exceptional periods.

To this end, the network management server 100 may provide a UI on the web page for inputting information on whether the exception event related to the registration of the exception pattern of the user is periodic or regular, if the event is a regular event.

However, the present invention is not limited to this, and if a leak alarm is provided to the user terminal 300 because the user does not register an exception pattern related to the exception event that occurs periodically, if it is confirmed that the exception event is periodic, A regular exception pattern may be registered by the management server 100 operator.

In addition to the pattern management service, the network management server 100 may provide various information inquiry services for real-time monitoring of the network and operation of the network. For example, the network management server 100 may include a real-time monitoring service for each flow / water pressure block, a periodical flow / water pressure inquiry service, a night minimum flow inquiry service, a usage status inquiry service per block, a night minimum flow analysis method, A leak rate calculation service through a specific block, and a yield rate inquiry service for a specific block. It is needless to say that the network management server 100 may provide the above-described various services together with various types of geographical information provided in the GIS server 3 in cooperation with the GIS (Geographic Information System) server 3.

A known technique can be used for the specific method of processing the measurement data obtained from the measurement means 200 and the geographical information obtained from the GIS server 3 for the network service management server 100 to provide the above service And is not related to the gist of the present invention, and thus a detailed description will be omitted.

Meanwhile, as described above, the user terminal 300 can access various services provided by the network management server 100 by accessing the network management server 100 through the Internet 2.

In particular, in order to use the pattern management service provided by the network management server 100, the user terminal 300 may request the network management server 100 to register a user-defined pattern and an exception pattern for a specific block in the water supply network . For example, the user terminal 300 accesses a web page managed by the network management server 100 for providing a service and sets the specified period, the allowable range, and the application period through the UI provided on the web page A user-defined pattern registration can be requested, and registration of an exception pattern can be requested by setting at least one of an exception period, an exception permission count, and an exception permission range.

Therefore, on the web page provided by the network management server 100, a user can set a designated period, an allowable range, and an application period to set up a user-defined pattern, a UI that can register at least one of an exception period, an exception permission count, A UI for registering an exception pattern can be displayed.

2A and 2B show an example of a UI capable of registering a user defined pattern and an exception pattern provided by the network management server 100. [

Referring to FIG. 2A, the user views the flow data for a specific block at 00:00 on November 17, 2008, and 10:24 on November 20, 2008, You can see that the flow data is displayed in the flow pattern. Accordingly, the user can register the user defined pattern by setting the application period while viewing the displayed flow pattern. At this time, the user can input the correction value to correct the displayed flow rate pattern, and may give the pattern ID to the user defined pattern to be registered.

On the other hand, FIG. 2B shows a UI capable of registering an exception pattern. As shown in FIG. 2B, a user can register an exception pattern by setting an exception period, an exception permission count, and an exception range. At this time, an exception pattern can also be given an ID.

On the other hand, the user sets the application period, and registers a new user defined pattern by matching the previously registered user defined pattern and the exception pattern to the corresponding application period. To this end, a UI for selecting a user defined pattern and an exception pattern previously registered for each application period may be displayed on a web page provided by the network management server 100.

Figure 2C shows an example of such a UI. Referring to FIG. 2C, the user applies the user-defined pattern 5 of the user name Y009 and the exception pattern 6 of the user name E003 in the application period from 00:00 on September 20 to 23:59 on October 25 And register a custom pattern (4) of the new ID T001.

On the other hand, the user terminal 300 can output a leakage alarm provided from the network management server 100. At this time, the leakage alarm may include at least one of an alarm or warning message that the real-time flow data value of the specific block exceeds the allowable range based on the flow data value on the corresponding user-defined pattern, but is not limited thereto.

Also, the user terminal 300 can access the network management server 100 and use a service for real-time monitoring of the flow rate of a specific block based on a user-defined pattern. Specifically, the user terminal 300 accesses the network management server 100 to request the flow monitoring of a specific block, and accordingly, real-time flow data and a user-defined pattern for the specific block from the network management server 100 If provided, it can be received and displayed as a graph over time. At this time, the graph displayed on the user terminal 300 may be, for example, as shown in FIG. 5, but is not limited thereto.

Hereinafter, the operation of the network management server 100 and the network management system will be described in more detail with reference to the specific configuration of the network management server 100 shown in FIG. 1 and FIGS. 3 to 5. At this time, a description overlapping with the above description is omitted.

According to the network management server 100 shown in FIG. 1, the network management server 100 includes a collecting unit 110, a database unit 120, a user-defined pattern registering unit 130, and a leak alarm unit 140.

The collecting unit 110 collects various measurement data including flow rate data from the measuring unit 200 that measures water pressure, flow rate, and water quality of a constant water in each block installed in each block of the blocked water supply network . Also, the collecting unit 110 may collect various types of geographical information including the water supply pipe network from the GIS server 3. [

The database unit 120 may store various kinds of programs for receiving and storing various measurement data and geographical information from the collecting unit 110 and calculating and analyzing the measurement data and the geographical information. In particular, the database 120 may store flow data corresponding to the measured time and stored for each block, and may store information on registered user defined patterns and exception patterns.

When the user pattern registration unit 130 requests the user terminal 300 to register a user-defined pattern for a specific block, the user-defined pattern registration unit 130 registers the user-defined pattern corresponding to the designation period included in the user- A flow pattern corresponding to a time of the specific block may be generated using the flow data for the specific block, and the generated flow pattern may be registered as a user defined pattern.

3 (a) is a graph showing the flow data of October 10, 2010 and October 11, 2010 of a specific block stored in the database unit 120 according to time. As shown in FIG. 3 (a), it can be seen that the flow pattern of the specific block is similarly repeated in units of one day. Therefore, the user can use the flow rate data stored in the database unit 120 for a specific block as a user-defined pattern that serves as a reference for monitoring the flow rate variation of the specific block.

Accordingly, if the user-defined pattern registration unit 130 requests the user terminal 300 to register a user-defined pattern having a designation period of October 10, 2010 and an application period of November 1 to November 5, 2011, The flow pattern is generated using the flow data of October 10, 2010 stored in the database unit 120, and the generated flow pattern is applied from November 1, 2011 to November 5, 2011, Can be registered.

Meanwhile, registration of the user-defined pattern by designating the designation period and setting of the application period of the registered user-defined pattern can be performed in a separate process. That is, when the user requests registration of the user-defined pattern to the network management server 100 through the user terminal 300, it is not necessarily required to set the designation period and the application period at the same time to request registration, A user can define one or more user-defined patterns by setting a period and select a registered user-defined pattern to set an application period for each selected user-defined pattern.

Specifically, when a user-defined pattern registration request including one or more designated periods is requested from the user terminal 300, the user-defined pattern registration unit 130 registers the flow rate corresponding to each designated period of the flow rate data stored in the database unit 130 Data can be used to register each user-defined pattern. If the user-defined pattern registration unit 130 requests the user-defined pattern registration from the user terminal 300 and the user-defined pattern to be applied to the application period is selected and the user-defined pattern registration is requested, the user- You can register a custom pattern. At this time, it is natural that an exception pattern may be registered together with a user-defined pattern. Figure 4 shows an example in which an annual user defined pattern is registered accordingly.

The leakage alarm unit 140 calculates a difference between the real-time flow rate data value and the flow rate data value on the user-defined pattern corresponding to the specific block, and when the difference value exceeds the allowable range, Alarms can be provided.

5 is a graphical representation of real time flow data of a particular block and corresponding flow data on a user defined pattern. Specifically, FIG. 5A shows a case where the difference value does not exceed an allowable range, and FIG. 5B shows an example of a case where the difference value exceeds an allowable range. At this time, the allowable range is assumed to be 100.

5 (a), the leak alarm unit 140 determines that the real-time flow rate data has a normal flow rate pattern and does not generate a leakage alarm. On the other hand, in the case of FIG. 5 (b) Since the difference between the flow rate data value and the flow rate data value on the user-defined pattern is suddenly increased after 13:00 and the difference value of the flow rate data value on the corresponding user-defined pattern exceeds the allowable range, the leakage alarm section 140 can notify the user terminal 300 of the leakage alarm .

Meanwhile, the user-defined pattern registering unit 130 may register an exception pattern including a condition that does not provide a leak alarm. In this way, when the exception pattern is registered, even if the difference value between the real-time flow rate data value of the specific block and the flow rate data value on the user-defined pattern corresponding thereto exceeds the allowable range, It is determined whether or not the condition is satisfied. If the condition is satisfied, the leakage alarm is not provided to the user terminal 300.

For example, even in the case of FIG. 5 (b), if an exception pattern having an exception period between 13:00 and 15:00 is registered, even if the difference value exceeds the allowable range, a leak alarm Is not generated.

As described above, the condition included in the exception pattern may further include an exception permission count or an exception permission range in addition to the exception period. Specifically, the allowable number of exceptions refers to the allowable number at which the leakage alarm does not occur even when the difference exceeds the allowable range, and the exception allowable range refers to the limit at which the difference value can exceed the allowable range.

In addition, each of the components of the network management server 100 described above may be implemented as separate components and connected to each other to perform the operations of the network management server 100 described above. For example, the collecting unit 110, the user-defined pattern registering unit 130, and the leak alarm unit 140 are each implemented as separate servers, and the database unit 120 is constructed as a separate DB, The network management server 100 may perform the operation of the network management server 100.

6 is a flowchart illustrating a network management method using a blocked waterworks network management system according to an embodiment of the present invention. In describing the network management method according to FIG. 6, a detailed description of the same contents as those described above with reference to FIGS. 1 to 5 will be omitted.

Referring to FIG. 6, when the flow rate data for each block of the water supply network is measured by the measurement unit 200, the network management server 100 stores the measured flow rate as flow data for each block (S610). At this time, the measurement unit 200 measures the number of times the measurement is performed by the network management server 100 every predetermined period through a wired or wireless communication network 1 such as a mobile communication network or a KT exclusive line or whenever a request is made by the network management server 100 Data can be transmitted, and the network management server 100 can receive and store the data.

Then, when the user terminal 300 requests the user-defined pattern registration for a specific block through the Internet 2, the network management server 100 stores the flow pattern data included in the user- The flow rate data according to the time is generated using the flow rate data corresponding to the designated period, and the generated flow rate data can be registered in the user defined pattern (S620).

Here, the user-defined pattern is a pattern that is a reference of the flow rate variation of a specific block that the user wants to manage, and means a flow pattern defined by the user setting at least one of a designation period, an application period, and an allowable range.

Meanwhile, an exception pattern including a condition that does not provide a leak alarm may be registered in the user-defined pattern. At this time, the above condition may include at least one of an exception period, an exception permission count, and an exception permission range.

At this time, the exception pattern can be registered in the network management server 100 through the user terminal 300 according to the obtaining of the exception event occurrence information generated in the specific block. If the exception event is an event that occurs regularly, It may be automatically registered on the network management server 100 under the same condition as the condition included in the registered exception pattern every time the event occurrence comes.

On the other hand, the network management server 100 compares the real-time flow rate data value for the specific block with the flow rate data value on the user-defined pattern corresponding thereto and calculates the difference value (S630) It is judged whether or not the leakage alarm is provided by judging whether or not the range is over and whether the registration of the exception pattern and the condition included in the exception pattern are satisfied.

Specifically, if the calculated difference value exceeds the allowable range (Yes in S640), and the exception pattern is not registered (S650, No), the network management server 100 provides a leak alarm to the user terminal 300. [ Also, even if the exception pattern is registered (Yes in S650), if the condition included in the exception pattern is not satisfied (No in S660), the leakage alert is provided to the user terminal 300. [

However, even if the calculated difference value does not exceed the permissible range (S640, No) and the permissible range is exceeded (S640, Yes), the exception pattern is registered (S650, Yes) (S660, Yes), the network management server 100 determines that the network management server 100 is in a normal state, and does not provide a leak alarm to the user terminal device 300. [

According to various embodiments as described above, it is possible to monitor leakage generated in the pipe network by using a user-defined pattern based on the flow data accumulated for each block, and to generate unnecessary alarms when the real time flow data is out of the allowable range under normal circumstances . As a result, more efficient network management becomes possible.

The operation of each configuration of the network management server 100 and the network management methods using the network management system 10 according to various embodiments described above may be created by software and loaded into the network management server 100.

More specifically, according to one embodiment of the present invention, a method is provided for measuring a flow rate of a constant water for each block of a water supply pipe network and storing the measured flow rate as flow rate data for each block, When registration of a user-defined pattern for a block is requested, flow data according to time is generated using flow data corresponding to a designation period included in a user-defined pattern registration request among flow data stored for a specific block, Registering the data in a user-defined pattern, and providing leakage alarm when the difference between the real-time flow data value for the particular block and the flow data value on the user-defined pattern corresponding to the real-time flow data value exceeds the allowable range A non-transitory readable medium having stored thereon a program for performing a network management method uter readable medium) can be installed.

A non-transitory readable medium is a medium that stores data for a short period of time, such as a register, cache, memory, etc., but semi-permanently stores data and is readable by the apparatus. In particular, the various middleware or programs described above may be stored and provided in non-volatile readable media such as CD, DVD, hard disk, Blu-ray disk, USB, memory card, ROM,

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, but, on the contrary, It will be understood by those skilled in the art that various changes in form and detail may be made therein without departing from the spirit and scope of the present invention.

1: wired, wireless communication network 2: internet network
3: Geographic Information System (GIS) server
100: network management server 200: measurement means
300: user terminal
110: collecting section 120: database section
130: user pattern registration unit 140: real-time monitoring unit

Claims (12)

A pipe network management system for a water supply system block-by-unit block,
Measuring means installed in each block of the water supply pipe network for measuring a flow rate of water in each block;
Acquiring and storing the flow rate data measuring the flow rate of the constant from the measuring means and comparing the real time flow rate data value with the stored flow rate data value and providing a leakage alarm when the difference value exceeds the allowable range; And
And a user terminal connected to the network management server to request registration of a user-defined pattern for a specific block, and to output the leakage alarm,
The network management server includes:
Generates a flow pattern according to time using flow data corresponding to a designation period included in the user defined pattern registration request among the flow data stored for the specific block, registers the generated flow pattern in the user defined pattern And providing the leakage alarm when the difference between the real time flow rate data value for the specific block and the flow rate data value on the user defined pattern corresponding to the real time flow rate data value exceeds the allowable range,
If an exception pattern including a condition for not providing the leakage alarm is registered together with the user defined pattern, if the condition is satisfied, the leakage alarm is not provided even when the difference value exceeds the allowable range,
The management network server comprises:
Acquiring measurement data on hydraulic pressure and water quality together with the flow rate data of the constant through the measurement means,
In the exception pattern,
An exception permission count, and an exception permission range, and receives an exception event occurrence information generated in the specific block through the user terminal, and receives at least one of an exception period, an exception permission count, and an exception permission range, The event is registered under the same condition as the condition for each period in which the exception event is generated according to the occurrence condition of the exception event, and even when it is confirmed that the exception event is periodic, , ≪ / RTI >
The user-
Based on the flow pattern generated by using the flow data corresponding to the selected designation period, at least one of the user's arbitrary correction value, the allowable range, the exception pattern, and the pre-registered user definition pattern is intermittently or continuously Application period, respectively,
The network management server includes:
(ID) to each of the user-defined pattern and the exception pattern so that the user-defined pattern and the exception pattern can be respectively identified, and the user-defined pattern and the real-time flow rate data are graphically displayed through the user terminal ,
A real time monitoring service for each flow / water pressure block, a flow / water pressure inquiry service for each period, a minimum flow rate inquiry service at night, a usage status inquiry service for each block, A leakage amount estimation service through a night minimum flow analysis method or a generalized water balance analysis method, and a service rate inquiry service for a specific block in a period of time
Network management system. delete delete delete delete delete A method of managing a pipe network using a pipe network management system of a block water supply system,
Measuring a flow rate of a constant water for each block of the water supply network and storing the measured flow rate as flow rate data for each block;
When a registration of a user-defined pattern for a specific block among the blocks is requested, a flow pattern corresponding to a time is calculated using flow data corresponding to a designation period included in the user-defined pattern registration request among the flow data stored for the specific block And registering the generated flow pattern in the user defined pattern;
Providing a leakage alarm when the difference between the real-time flow rate data value for the specific block and the flow rate data value on the user-defined pattern corresponding to the real-time flow rate data value exceeds an allowable range; And
And registering an exception pattern including a condition that does not provide the leakage alarm,
The step of storing the flow rate of the constant as the flow rate data for each block includes:
And obtaining measurement data on the water pressure and the water quality together with the flow rate data of the constant through the measurement means,
The step of registering the exception pattern comprises:
Wherein the exception pattern includes at least one of an exception period, an exception permission count, and an exception permission range by receiving exception event occurrence information generated in the specific block through the user terminal, The event is registered under the same condition as the condition for every occurrence of the exception event according to the occurrence condition of the exception event, and even when it is confirmed that the exception event is periodical, And registering the same with the same condition as the condition,
Wherein the step of registering with the user-
Based on the flow pattern generated using the flow data corresponding to the selected designation period, reflects at least one of the user's arbitrary correction value, the allowable range, the exception pattern, and the pre-registered user definition pattern So as to be applied to each of the intermittent or continuous application periods; And
(ID) is assigned to each of the user-defined pattern and the exception pattern so that the user-defined pattern and the exception pattern can be respectively identified, and the user-defined pattern and the real-time flow rate data are displayed as a graph through the user terminal ; ≪ / RTI >
A real time monitoring service for each flow / water pressure block, a flow / water pressure inquiry service for each period, a minimum flow rate inquiry service at night, a usage status inquiry service for each block, Providing a leak rate estimation service through a night minimum flow analysis method or a generic water balance analysis method, and a service rate inquiry service for a specific block in a period of time
Network management method. delete delete A pipe network management server of a water supply system block-by-unit block,
A collection unit installed in each block of the water supply pipe network and collecting flow rate data of the constant flow measured by the measuring means for measuring the flow rate of the constant water for each block;
A database unit for receiving and storing the flow rate data from the collecting unit;
When a registration of a user-defined pattern for a specific block is requested from a user terminal, flow data corresponding to a designation period included in the user-defined pattern registration request among the flow data for the specific block stored in the database unit is used A user-defined pattern registration unit for generating a flow pattern according to the user-defined pattern and registering the generated flow pattern in the user defined pattern; And
And a leak alarm unit for providing a leakage alarm to the user terminal when the difference between the real time flow rate data value for the specific block and the flow rate data value on the user defined pattern corresponding to the real time flow rate data value exceeds the allowable range ,
Wherein the user-
Further registering an exception pattern including a condition for not providing the leak alarm,
The leak alarm unit includes:
If the condition is satisfied, the leakage alarm is not provided even when the difference value exceeds the allowable range,
Wherein,
Acquiring measurement data on hydraulic pressure and water quality together with the flow rate data of the constant through the measurement means,
Wherein the user-
Wherein the exception pattern includes at least one of an exception period, an exception permission count, and an exception permission range by receiving exception event occurrence information generated in the specific block through the user terminal, The event is registered under the same condition as the condition for every occurrence of the exception event according to the occurrence condition of the exception event, and even when it is confirmed that the exception event is periodical, To be registered under the same condition as the condition,
Based on the flow pattern generated using the flow data corresponding to the selected designation period, reflects at least one of the user's arbitrary correction value, the allowable range, the exception pattern, and the pre-registered user definition pattern And applying them to intermittent or continuous application periods, respectively,
The database unit,
(ID) to each of the user defined pattern and the exception pattern so that the user defined pattern and the exception pattern can be respectively identified, and the user defined pattern and the real time flow rate data are graphically displayed on the user terminal ,
A real time monitoring service for each flow / water pressure block, a flow / water pressure inquiry service for each period, a minimum flow rate inquiry service at night, a usage status inquiry service for each block, A leakage amount estimation service through a night minimum flow analysis method or a generalized water balance analysis method, and a service rate inquiry service for a specific block in a period of time
Network management server. delete delete

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