KR102193382B1 - Smart metering-based indoor water leakage detection system - Google Patents

Abstract

The present invention relates to a smart metering-based indoor water leakage detection system which uses remote metering in a suspicious indoor water leakage customer measured by a meter when water is unintentionally used by a failure in a water pipe, a bathroom utility, a boiler, and the like to check water leakage. According to the present invention, the smart metering-based indoor water leakage detection system comprises: a digital meter measuring an amount of water used by a user through a water pipe in a protective container; a wireless communication terminal transmitting information measured by the digital meter to a repeater provided outside the protective container; a user terminal of the user and a building manager of a house having the water pipe installed therein; a database storing information about the user, measurement information measured in a digital meter, and information about the wireless communication terminal; and a management server connected to the wireless communication terminal and the user terminal through the repeater and transmitting leakage status information to the user terminal in accordance with the information transmitted from the wireless communication terminal. The management server includes a water leakage management module elastically changing a remote metering period to verify water leakage and manage information about an indoor water leakage status, thereby being capable of correctly determining the indoor water leakage of a customer.

Description

Smart metering-based indoor water leakage detection system

The present invention relates to a smart metering-based indoor leak detection system.In particular, tap water is unintentionally used due to failure of water pipes, bathroom supplies, boilers, etc., and the leak is checked using remote meter reading for suspected indoor leaks measured by a meter. It relates to an indoor leak detection system based on smart metering.

In general, tap water is treated at a water purification plant and then supplied through large pipes for each city in the case of a city, and tap water is classified into medium blocks and small blocks in each district to supply tap water. In addition, a water meter is installed between each distribution point to measure the flow rate of tap water supplied to the distribution area. For example, in large facilities such as apartment complexes, water pipes are installed to supply tap water through large pipes, and general homes and commercial buildings are connected from large pipes buried under the road to small pipes, which is the final use. It is supposed to supply tap water to customers.

Such pipelines are managed by local governments, and the indoor piping is the responsibility of each customer. However, since each customer does not have any means to detect whether there is leakage indoors, it is difficult for most customers to recognize whether or not a leak has occurred.

The method of determining the cause of such leakage is largely lost in time and economic costs by relying on human resources to recognize and judge the situation, and confusion due to sensor failure and malfunction occurs even in the case of determining a crisis situation through sensor installation. Rather, there was a problem that additional maintenance problems occurred.

In other words, it is virtually impossible to check the water meter of each indoor (house) regularly, and in reality, due to the lack of inspection personnel, there is no choice but to directly check whether there is a leak every one to three months. It is difficult to prevent the damage caused. In addition, there is a problem that it is not easy for each in-house user to directly check whether there is a leak.

On the other hand, recently, as a real-time measurement of usage from a water meter using a digital meter, data is produced by applying a remote meter reading, and the collected data is transmitted to a water service provider through a communication network, and water consumption is reduced by using a remote meter reading. In order to obtain effects such as water leakage management, supply and demand control, and energy savings, continuous meter reading values are continuously transmitted to the operating system to analyze the collected data.

For example, in order to determine abnormal signs with a leak alarm using a digital meter, according to the firmware of the digital meter indication unit, it is determined whether or not more than 1L is accumulated for 1 hour, and water is continuously used for 7 days or more based on the firmware of the digital meter indication unit. The digital meter may notify the leakage alarm when two conditions are satisfied, but the digital indicator of the digital meter operates once an hour and the usage is checked through the cumulative count of the number of revolutions of the lower blade (impella) of the meter. Since the amount of water is calculated, if the amount of water used within one hour is "0", even though it is not a leak, if the accumulated amount exceeds 1L, the condition is satisfied, so whether or not to determine the leak may be an error.

Therefore, in the digital meter leak alarm method, all products are configured in the same way as each digital meter manufacturer established the Seoul waterworks office, so it is possible to suspect a leak with a leak alarm from a digital meter, but there is a problem that an error occurs when checking.

An example of a technique for solving this problem is disclosed in Patent Documents 1 to 3 below.

For example, in Patent Document 1 below, a sound detection sensor installed in a water supply pipe to detect the sound of water transmitted through the water supply pipe, an output unit outputting information detected by the sound detection sensor, and the sound detection sensor It includes a control unit that analyzes the detected information to check whether there is a leak in the water supply pipe, and outputs the confirmation result through the output unit, and the sound detection sensor transmits the sound transmitted through the water supply pipe to the inside of the housing. About a water leak detection device comprising a sound transmission member, a vibration plate trembling by the sound transmitted into the housing through the sound transmission member, and a sound collection unit that collects the vibration of the vibration plate and transmits it to the control unit. It is disclosed.

In addition, in Patent Document 2 below, an hourly usage information calculation process that obtains hourly usage information from collected meter reading information, a minimum hourly usage information selection process for selecting the minimum hourly usage within a set time period, and the minimum hourly usage information and minimum When the minimum hourly usage information is larger than the minimum usage reference value information by comparing the usage reference value information, a leak determination process that determines whether there is an indoor leak, and if it is determined as a leak through the leak determination process, the minimum usage reference value is determined from the minimum hourly usage information. Remote meter reading including a leak calculation process that calculates the estimated amount of water leakage, and a leak notification process that informs the leak information including the leaked amount and the expected amount of leakage using contact information registered in the corresponding customer information when indoor leakage is determined through the leak determination process. Disclosed is a control method for determining indoor leakage in a system.

Meanwhile, in Patent Document 3 below, measuring the flow rate of water entering indoors through a meter reader and transmitting the measured value to a repeater, the measured value of the flow rate measured by the meter reader through the repeater is collected and analyzed in real time or for a certain period of time. Transmitting to the server, analyzing the amount of background loss, indoor leakage, excessive flow, indoor inflow, indoor usage, and drainage pipe leakage through the analysis server, converting the analysis result analyzed by the analysis server into a DB and outputting the analysis result DB A method of remote meter reading comprising the step of converting the measured value into a DB to generate a measured value DB, and storing it together with the analysis result DB is disclosed.

Korean Registered Patent Publication No. 10-1250955 (registered on March 29, 2013) Korean Registered Patent Publication No. 10-1214986 (registered on December 17, 2012) Korean Patent Publication No. 10-1758343 (registered on July 10, 2017)

In the technology disclosed in Patent Document 1 as described above, a sound sensor is installed to be connected to a water supply pipe and is a structure that detects the loudness of the sound transmitted through the water pipe. In the case of failure of water pipes, bathroom supplies, and boilers, Since it is necessary to remove the floor of a kitchen or bathroom and install a sound sensor, there is a problem that it is not possible to detect indoor water leakage.

In addition, in Patent Document 2, since the leak determination unit obtains hourly usage information every hour, selects the minimum usage amount among the hourly usage information within 72 hours, and compares it with the minimum usage reference value set for the customer to determine whether or not there is a leak, If the amount of water used within 1 hour is "0", there is a problem that even though it is not a leak, if the accumulated amount exceeds 1L, it is judged as a leak and the leak determination is not executed accurately. That is, in the technology disclosed in Patent Document 2, for example, since continuous meter reading, variable period, minimum flow rate check, etc. are not applied, there may be a suspicion of leakage, but there is a problem that accurate leakage cannot be determined.

On the other hand, in the technology disclosed in Patent Document 3, the flow rate of water entering indoors for 1 to 4 minutes is measured at intervals of 1 to 4 hours, and when the difference in the flow rate of water per minute is less than the difference reference value, the measured value is the indoor water supply pipe. Indoor leakage is determined by analyzing the amount of background loss, but since the technology disclosed in Patent Document 3 does not apply continuous meter reading and variable periods, there is a problem that accurate leakage cannot be determined.

In the case of checking the amount of usage at 1-hour intervals in the technology disclosed in the patent literature as described above, the actual leak is identified by the use of equipment that automatically water supply periodically, such as toilets, boilers, water purifiers, and pot water dispensers, or by changing the customer's lifestyle. There was a problem that I couldn't.

An object of the present invention has been made to solve the above-described problems, and after selecting a suspected leak target, the remote meter reading period is flexibly changed to verify the leak to determine accurate indoor leak detection. To provide a system.

Another object of the present invention is to provide a smart metering-based indoor leak detection system that can reduce water bills of customers through accurate diagnosis of indoor leaks, reduce indoor leak test cost, and efficiently operate water resources.

In order to achieve the above object, the smart metering-based indoor leakage detection system according to the present invention is a smart metering-based indoor leakage detection system that verifies leakage by flexibly changing a remote meter reading period after selecting a suspected leakage target. A digital meter that measures the amount of water used by a user through a water supply pipe, a wireless communication terminal that transmits information measured by the digital meter to a repeater provided outside the protection container, a home user or a building manager in which the water supply pipe is provided A user terminal such as a user terminal, user information, measurement information measured by the digital meter, a database storing information on the wireless communication terminal, and the wireless communication terminal and the user terminal through the repeater, and the wireless communication terminal And a management server that transmits the leak status information to the user terminal according to the information transmitted from, and the management server verifies the leak by flexibly changing the remote meter reading period to manage information on the indoor leak status. It characterized in that it includes.

In addition, in the smart metering-based indoor leak detection system according to the present invention, the leak management module analyzes a pattern of water usage per hour of the suspected leaking customer in the suspected leak target selection unit and the leak suspect target selection unit Or, a customer leak check unit that checks the leak by changing the meter reading cycle for the customer reviewed in the indoor leak abnormal symptom review unit that reviews the indoor leakage abnormality symptom based on the starting flow rate, and the customer leak check. It characterized in that it comprises a customer leak notification unit for notifying the state of the indoor leak to the customer identified as an indoor leak.

In addition, in the indoor leakage detection system based on smart metering according to the present invention, the indoor leakage abnormality symptom review unit is based on Big Data, a lifestyle pattern in which the water consumption is the minimum amount during the early morning hours, the previous usage-based pattern as an increase compared to the amount used in the last month or last week, It is characterized by examining the signs of abnormal indoor water leakage by analyzing the pattern based on the surrounding usage by the amount of increase in water consumption compared to the customer at the same level.

In addition, in the indoor leakage detection system based on smart metering according to the present invention, the indoor leakage abnormality symptom review unit analyzes as an indoor leakage symptom if the water usage per hour is not detected below the starting flow rate for a certain period to review the indoor leakage abnormality symptoms of the customer. It is characterized.

In addition, in the smart metering-based indoor leak detection system according to the present invention, the customer leak confirmation unit is compact in units of 1 to 10 minutes for the customer's digital meter in the weighing management module for the customer reviewed by the indoor leak abnormality symptom review unit. If the water consumption of the customer managed by the metering management module is "0 (no use)" or the minimum flow rate, it is confirmed that it is not a leak, and if the metered consumption exceeds the minimum flow rate, the customer is leaked. It characterized in that it is confirmed by.

In addition, in the indoor leak detection system based on smart metering according to the present invention, the digital meter is characterized by having a continuous use alarm function and a function of measuring the amount of water used in units of 0.0001㎥ and transmitting it to a wireless communication terminal.

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As described above, according to the indoor leak detection system based on smart metering according to the present invention, by providing a leak management module that manages information on the indoor leak state by flexibly changing the remote meter reading period to verify the leak, The effect of being able to accurately detect the indoor leak condition is obtained.

In addition, according to the smart metering-based indoor leak detection system according to the present invention, the leak management module can accurately diagnose indoor leaks to reduce water bills for customers and reduce the cost of indoor leak testing.

1 is a block diagram of a smart metering-based indoor leak detection system according to the present invention,
FIG. 2 is a block diagram for explaining the configuration of the wireless communication terminal shown in FIG. 1;
3 is a block diagram for explaining the configuration of the management server shown in FIG. 1;
4 is a block diagram showing the configuration of the leak management module shown in FIG. 3;
5 is a sequence diagram of a protocol for checking indoor leakage between a digital meter, a wireless communication terminal, a management server, and a user terminal in the smart metering-based indoor leakage detection system according to the present invention.

The above and other objects and new features of the present invention will become more apparent from the description of the present specification and the accompanying drawings.

As used herein, the term "indoor leak" means that tap water is unintentionally used due to failure of water pipes, bathroom supplies, and boilers, and is measured by a meter, and unintended water consumption is measured by a meter. In addition, "starting flow rate" refers to the lowest flow rate at which a clear change is observed when water is passed through the meter as the flow rate started by the guide (impeller) of the water meter, and the diameter of the meter or the description of the manufacturer. Depends on, the unit can be applied to L/h.

The water meter applied to the present invention can be installed not only in the water supply pipe used in the home, but also in the water supply pipes used in all kinds of water use places such as buildings, by applying a digital meter mounted on the water supply pipe provided in the protective container. .

Such a digital meter consists of a flow meter provided to allow the naked eye to read the numerical value between the water pipes. Specifically, the flow meter has a built-in general meter reading device, so the impeller rotates according to the flow rate of tap water passing through the inside. The flow rate according to the number of revolutions of the impeller is to be metered. In addition, the digital meter applied to the present invention has a leak alarm function, a continuous use alarm function, and a function of transmitting up to 0.0001㎥ units measured by the flow meter.

In the indoor leak detection system based on smart metering according to the present invention, a wireless communication terminal may be installed inside a protective container such as a general water pipe protection container, and the communication between the wireless communication terminal and the repeater is LoRa (Long Range). ) Method, Narrowband Internet of Things (NB-IoT) method, UNB (Ultra Narrow-Band) modulation method, Wi-Sun (Smart utility networks) method, ZigBee method, ISM (Industry-Science-Medical) band method , RF communication method, Bluetooth (BLE) method can be implemented in any one of. In addition, the wireless communication terminal not only delivers the usage value at fixed intervals, but also has a function of densely delivering continuous usage by changing the period at the instruction of the management server.

In addition, the smart metering-based indoor leak detection system according to the present invention is a system that basically uses remote meter reading to check the suspected leak, and additional verification costs such as on-site inspection are incurred even if the suspected leaking customer is selected based on various reasons. In order to solve the problem, customers who suspect water leakage should continuously read the meter closely in units of approximately 1 to 10 minutes to confirm non-use or minimum flow rate, and save battery as both digital meters and wireless communication terminals must be used with batteries for a long time. In the meantime, a short period is variably set, and the meter reading period is variably received over a certain period of time and the meter reading value is analyzed. When the indoor water supply is not used or the minimum flow rate occurs, a system is provided to confirm that there is no leakage.

Hereinafter, embodiments according to the present invention will be described with reference to the drawings.

FIG. 1 is a block diagram illustrating a system for detecting water leaks in an indoor based on smart metering according to the present invention, and FIG. 2 is a block diagram illustrating the configuration of a wireless communication terminal shown in FIG. 1.

The configuration diagram of the indoor leak detection system based on smart metering according to the present invention is a water supply pipe provided in a protection container, as shown in Figs. 1 and 2, the amount of water used by a user through the water supply pipe within the protection container is measured. A digital meter (10), a wireless communication terminal (20) that transmits information measured by the digital meter (10) to a repeater (60) provided outside the protective container, a home user or a building manager equipped with a water pipe Through the database 40 and the repeater 60 storing information on the user terminal 30 such as the user terminal 30, the user information, the measurement information measured by the digital meter 10, the wireless communication terminal 20 It is connected to the wireless communication terminal 20 and the user terminal 30, and includes a management server 50 for transmitting the leak state information to the user terminal 30 according to the information transmitted from the wireless communication terminal 20. .

As described above, the digital meter 10 is fixedly installed on a horizontal pipe of an inlet water pipe such as a general home, commercial facility, apartment house, and apartment, and a leakage alarm function, continuous use alarm function, and 0.0001㎥ unit measured by a flow meter It is equipped with a function to deliver to.

In the existing leak alarm digital meter, when the first use is detected, the leak alarm function is started. For example, if the condition of accumulated usage of 1L or more for 60 minutes occurs continuously for 7 days, a leak alarm occurs, but for example, every 20 minutes There was a problem that a leak alarm occurs when 1L of water is used in and the water is not used for the rest of the time. In order to solve this problem, the digital meter 10 applied to the present invention detects continuous use rather than usage, and continuously detects continuous use at intervals of less than 1 second by impeller operation, so that continuous use is detected by firmware without a separate circuit configuration. . For example, if continuous use is repeated for more than 3 days at 1-second intervals, a leak alarm is issued.

In addition, the existing leak alarm digital meter can display 0.0001 or 0.00001 on the display and up to 10mL or 1mL, but only 0.001 or 1L units are transmitted to the wireless communication terminal and the rest is discarded. That is, it is possible to measure 10 mL units with one impeller rotation, but since it is not a unit for calculating charges, 10 mL units were cut.

However, in order to determine the leakage, it is necessary to detect a minute amount of use, so the digital meter 10 applied to the present invention accurately transfers the amount of use to the wireless communication terminal 20 up to 10 mL units.

The wireless communication terminal 20 is provided in a protective container and has a function of not only delivering usage values at fixed intervals, but also delivering continuous usage densely by changing the period at the instruction of the management server 50. As shown in Fig. 2, an interface unit 21 connected to the digital meter 10 by wire, a display unit 22 displaying the metering data of the digital meter 10 so that a meter reader can check the metering data, The control unit 23 to manage, the wireless communication module 25 for transmitting the metering data of the water supply pipe from the control unit 23 to the repeater, the display 22, the control unit 23 and the wireless communication module 24 It includes a power supply unit 25 supplying necessary power.

The interface unit 21 connects the digital meter 10 and the wireless communication terminal 20 with a wired cable, and transmits the accumulated flow data of the customer in the digital meter 10 at a predetermined interval, for example, 1 per hour. Every 24 times a day or at regular intervals according to the change in meter reading period, it is delivered from the wired cable, and the metering information is processed by RS232 method or TTL (pulse coding) method. As described above, since the interface unit 21 connects the digital meter 10 and the wireless communication terminal 20 with a wired cable, the wireless communication terminal 20 can be easily mounted at an appropriate position in the protective container. have.

The display unit 22 is made of an LCD, etc., and is a display device for allowing a meter reader to check the metering data of the digital meter 10, and displays the data when metering is controlled by the control unit 23, and To reduce the battery consumption of (25), it is displayed only for a certain period of time after pressing the button. However, when the meter reader can read the metering data by the digital meter 10, the display unit 22 may be omitted in the wireless communication terminal 20. By omitting the structure of the display unit 22, the wireless communication terminal 20 can be manufactured in a small size, and thus manufacturing cost can be reduced.

The control unit 23 includes a memory composed of a microprocessor and a nonvolatile memory, and in order to reduce power consumption in the power supply unit 25, measurement information of the digital meter 10 and meter reading period are It collects the weighing information and controls to transmit the collected weighing information to the repeater 60 through the wireless communication module 24. That is, the control unit 23 controls the wireless communication module 24 to collect the metering information of the digital meter 10 at fixed regular intervals and transmit it to the management server, but according to the instructions of the management server 50, the digital meter By changing the period and measurement amount of the metering information in (10), continuous usage can be densely transmitted to the management server 50.

The wireless communication module 24 is a digital meter 10 collected from the wireless communication terminal 20, which provides a function of wirelessly transmitting and receiving metering data that measures the amount of water used by the user through a water supply pipe to the management server 50. In charge. The wireless communication terminal 20 applied to the indoor leak detection system according to the present invention is driven by the battery, which is the power supply unit 25, because the phase change is not supplied, and the water supply digital meter 10 has a replacement cycle of 8 years. The battery performance of the communication terminal 20 must also maintain the function of the digital meter 10 or more, for example, at least 8 years.

Therefore, the wireless communication module 25 is designed as a system for transmitting and receiving low-capacity data based on low power, for example, a LoRa (Long Range) method, a Narrowband Internet of Things (NB-IoT) method, and an Ultra Narrow (UNB) method. -Band) Modulation method, Wi-Sun (Smart utility networks) method, ZigBee (ZigBee) method, ISM (Industry-Science-Medical) band method, RF communication method, it can be implemented in any one of the Bluetooth (BLE) method.

As described above, the power supply unit 25 preferably employs a battery that maintains a function of 8 years or more, which is more than the replacement period of the digital meter 10 as described above.

The database 40 is a general storage device that stores information on a user, measurement information measured by the digital meter 10, information on the wireless communication terminal 20, etc., in developing a specific device It is constructed by the database construction theory (or Ontology DB construction theory) in consideration of the ease and efficiency of access and search. That is, in the database 40, the address of the customer, the phone number of the user terminal, etc. are stored as information about the user for remote management of the water supply, and the information on the management number and the installation location of the digital meter 10, a digital meter ( As the measurement information measured in 10), measurement data, which is the amount of water used by the user through the water supply pipe, is accumulated and stored, and information on the installation period of the wireless communication terminal 20 as information about the wireless communication terminal 20, and a management number And information on the installation location is stored.

Next, the configuration of the management server 50 will be described according to FIG. 3.

3 is a block diagram for explaining the configuration of the management server shown in FIG. 1.

The management server 50 is a conventional server, which is connected to the wireless communication terminal 20 and the user terminal 30 through the repeater 60, and according to the information transmitted from the wireless communication terminal 20, the user terminal ( 30) to provide a service for transmitting status information of the digital meter 10, which is a water meter. The management server 50 may be constructed to serve as a kind of web server or web service server. For example, the management server 50 displays the processed result on a web page or receives necessary input data through the web page. The web page includes not only simple text, images, multimedia, etc. but also driving software for performing specific tasks such as web applications. In addition, it may be built to provide an interface with an application (or software) installed on a smartphone or a tablet PC. In addition, the management server 50 may be provided as a dedicated server for the operation of the customer's digital meter 10 and the wireless communication terminal 20, but is not limited thereto and It can be prepared as a usable server.

Accordingly, the management server 50 is a user management module 51 that manages information on a user, as shown in FIG. 3, and a wireless communication terminal management that manages the location and state information of the wireless communication terminal 20. The module 52, the metering management module 53 for managing the amount of water used by the user, the leakage management module 54 for managing information on the indoor leakage state, the wireless communication terminal 20 and the user terminal 30 It includes a transmission/reception module 55 for performing wireless communication.

The user management module 51 manages user information on new subscribers or changes in the address of the customer, the phone number of the user terminal stored in the database 40, and the leakage management module 54 manages the user according to management. The phone number of the user terminal 30 for notifying the leak warning is extracted.

The wireless communication terminal management module 52 interlocks with the user management module 51 to provide information on the installation period and installation location of the wireless communication terminal 20 stored in the database 40 so that the wireless communication terminal 20 It is managed to be linked with the installed customer's user terminal.

The weighing management module 53 calculates the amount of water used for a certain period from the weighing data from the digital meter 10 transmitted through the wireless communication terminal 20 and manages to periodically transmit it to the user terminal 30, and In order to check the leak, it manages to calculate the amount of water used or the amount of water continuously used at variable periodic intervals according to an instruction from the water leakage management module 54.

The leakage management module 54 will be described with reference to FIG. 4.

4 is a block diagram showing the configuration of the water leakage management module shown in FIG. 3.

The leak management module 54 selects a customer who is a suspected indoor leak and then flexibly changes the remote meter reading period to verify the leak, as shown in FIG. 4, the digital meter 10 received through the transmission/reception module 55. ), based on the data collected every hour from the remote meter reading data or continuous use alarm, the leak suspected target selection unit 541 that suspects the customer's leaking signs, and the amount of use measured continuously in a digital meter (10). The customer leakage amount calculation unit 542 that continuously calculates the amount of leakage, the suspected leakage target selection unit 541 analyzes the pattern of water consumption per hour of the suspected customer to be leaked, and reviews signs of abnormal indoor leakage or digital meter (10) The indoor leakage abnormality symptom review unit 543, which reviews signs of leakage based on the starting flow rate at, and the customer leak check by changing the meter reading period for the customer reviewed in the indoor leakage abnormality symptom review unit 543 It includes a customer leak notification unit 545 for notifying the leak state to the customer identified as a leak in the customer leak confirmation unit 544 through the unit 544, the transmission/reception module 55.

The suspected leakage target selection unit 541 determines whether the digital meter 10 accumulated more than 1L for 1 hour in order to determine the signs of leakage using the digital meter 10 of the customer managed by the weighing management module 53 And, it is determined whether or not water is continuously used for 7 days or more, and when the two conditions are satisfied, the digital meter 10 selects a leaked customer as a suspected leak target. In addition, the suspected leakage target selection unit 541 may select a customer as a suspected leakage target according to a continuous use alarm in the digital meter 10.

The customer leakage amount calculation unit 542 calculates the amount of leakage based on the amount of consumption measured continuously by the digital meter 10 of the customer managed by the metering management module 53, and notifies the calculated leakage amount to the management authority Let's plan the reduction of

The indoor leakage abnormality symptom review unit 543 is based on a life pattern in which the amount of water consumption at dawn is the minimum amount based on Big Data, a pattern based on previous consumption as an increase compared to the amount used in the last month or last week, and an increase in the amount of water consumption at the same level. Analyze the usage-based pattern and review signs of abnormalities in indoor leaks of customers.

In general, leaks below the starting flow rate are insensitive and are not treated as leaks by the waterworks business division. In other words, it is generated by the water pressure of the tap water, and only leaks above the starting flow rate are recognized as leaks. For example, assuming a 13mm starting flow rate of 6L/h, when the actual water consumption for 1 hour is 0L or when the starting flow rate is 6L or less, it is determined that there is no leakage, and when the actual water consumption for 1 hour exceeds 6L Suspect a leak.

Accordingly, the indoor leakage abnormality symptom review unit 543 may review the leakage abnormality symptom based on the starting flow rate in the digital meter 10. That is, if the indoor leakage abnormality symptom review unit 543 does not detect less than the starting flow rate for a certain period of time, it may be determined as an indoor leakage symptom.

The customer leak check unit 544 is compact in units of approximately 1 to 10 minutes for the customer's digital meter 10 in the weighing management module 53 for the customer reviewed by the indoor leakage abnormality symptom review unit 543. If the water consumption of the customer managed by the metering management module 53 is "0 (no use)" or the minimum flow rate, it is confirmed that it is not a leak, and when the metered consumption exceeds the minimum flow rate, the customer price It is confirmed by the leak of. That is, the customer leakage confirmation unit 544 first from the indoor leakage abnormal symptom review unit 543 for a short period of time (eg, one day) the lowest frequency of use (eg, 01 o'clock to 4 o'clock) If there is 0 (no use) or the minimum flow rate (starting flow rate * unit time) in the unit measurement quantity by measuring the amount of use in a compact and continuous interval of 60 minutes to 1 minute, it is judged as normal, not leakage, and then detailed. Leakage of customers can be confirmed by re-inspection (re-inspection under various conditions) based on the lowest frequency of use (e.g., 01 o'clock to 4 o'clock) for a predetermined period (e.g., two days) longer than one specified period. have.

The leak notification unit 545 notifies the customer of the leak to the user terminal 30 through the transmission/reception module 55 with respect to the customer identified as a leak.

The transmission/reception module 55 is composed of a conventional transmission/reception module, and is provided to use the repeater 60 and a low-power wide-area (LPWA) network or a conventional network.

Meanwhile, in FIG. 4, the user management module 51, the wireless communication terminal management module 52, the weighing management module 53, and the water leakage management module 54 are shown as separate configurations, but the program is not limited thereto. It can also be configured to run by

The repeater 60 transmits information between the management server 50 and the wireless communication terminal 20 using a low-power wide-area (LPWA) network or manages the management using a normal network. The transmission of information is performed between the server 50 and the user terminal 30.

Next, a method of driving a smart metering-based indoor leak detection system according to the present invention will be described with reference to FIGS. 1 to 4 and 5.

5 is a sequence diagram of a protocol for checking indoor leaks between a digital meter, a wireless communication terminal, a management server, and a user terminal in the indoor leak detection system based on smart metering according to the present invention.

First, the metering data on the amount of water used by the user in the digital meter 10 is transmitted to the transmission/reception module 55 of the management server 50 through the wireless communication module 24 and the repeater 60 of the wireless communication terminal 20. Is transmitted. Such metering data may be measured and transmitted at 1 hour intervals, for example. In addition, the digital meter 10 transmits a leak alarm function, a continuous use alarm function, and a 0.0001㎥ unit measured by the flow meter to the management server 50.

The weighing management module 53 manages the weighing data as information on the amount of water used by the customer in connection with the database 40 and the user management module 51 and the wireless communication terminal management module 52.

On the other hand, the control unit 23 of the wireless communication terminal 20, for example, determines whether the measurement data from the digital meter 10 is accumulated over 1L for 1 hour, and continuously uses water for 7 days or more. When the two conditions are satisfied, the digital meter 10 determines that the leaked customer is a leak, or, for example, by the continuous use alarm function that repeats continuous use for 3 days or more at 1-second intervals, The leak suspicious information is transmitted to the management server 50.

The suspected leakage target selection unit 541 of the leakage management module 54 selects a suspected leakage target according to the suspected leakage information transmitted from the wireless communication terminal 20, and the indoor leakage abnormal symptom review unit 543 Based on data (Big Data), the life pattern of the minimum amount of water use at dawn, the pattern based on the previous use as an increase compared to the amount of use in the last month or last week, the pattern based on the surrounding consumption as an increase compared to the amount of water consumption at the same level, or in a digital meter (10). Based on the starting flow rate of the customer, examine the signs of abnormal leaks in the interior of the customer.

Accordingly, the leak check module 54 instructs the digital meter 10 of the customer through the weighing management module 53 to continuously read the digital meter 10 in approximately 1 to 10 minutes increments, and the period is varied and the metered data Is received by the metering management module 53, and the customer leak confirmation unit 544 confirms that the customer's water usage is "0 (no use)" or the minimum flow rate in the received fluctuation meter reading data as not a leak, and If the amount used exceeds the minimum flow rate, it is judged as a customer leak.

According to the determination of the customer leak confirmation unit 544, the leak notification unit 545 notifies the customer of the leak to the user terminal 30 through the transmission/reception module 55 for the customer identified as a leak. In addition, the customer leakage amount calculation unit 542 calculates the amount of leakage based on the amount of consumption measured continuously by the digital meter 10 of the customer managed by the metering management module 53, and notifies the calculated leakage amount to the management office, Let's plan the reduction of

On the other hand, in the case where the customer leak check unit 544 does not leak the customer, the suspected leak target selection unit 541 processes the suspected leak target of the customer to be excluded.

The indoor leakage of the customer can be accurately determined by determining the leakage in the leakage management module 54 as described above.

Although the invention made by the present inventor has been described in detail according to the above embodiment, the invention is not limited to the above embodiment, and can be changed in various ways without departing from the gist of the invention.

By using the indoor leak detection system based on smart metering according to the present invention, it is possible to accurately determine the indoor leak of the customer.

10: digital meter
20: wireless communication terminal
30: user terminal
40: database
50: management server
60: repeater

Claims (10)

As an indoor leak detection system based on smart metering that checks the leak by flexibly changing the remote meter reading cycle of the water meter after selecting the suspected indoor leak target,
Digital meter that measures the amount of water used by the user through the water supply pipe in the protective container and detects continuous use,
A wireless communication terminal that transmits information precisely measured in the digital meter to a unit of 10 mL to a repeater provided outside the protective container,
User terminals such as a home user or a building manager in which the water pipe is provided,
A database for storing information on the user, measurement information measured by the digital meter, and information on the wireless communication terminal; and
And a management server connected to the wireless communication terminal and the user terminal through the repeater, and transmitting leakage state information to the user terminal according to information transmitted from the wireless communication terminal,
The management server includes a water leakage management module for managing information on indoor water leakage conditions by flexibly changing a remote meter reading period to verify water leakage,
The leak management module
In order to determine signs of leakage, the digital meter determines whether or not the digital meter has accumulated more than 1L for 1 hour, determines whether or not water has been continuously used for 7 days or more, and when two conditions are satisfied, the customer is selected as a suspected leakage target. Suspicious target selection department,
An indoor leak abnormality symptom review unit that analyzes a pattern of water consumption per hour of a suspected leaking customer in the above suspected leak target selection unit or examines indoor leakage abnormalities based on starting flow rates,
Including a customer leak check unit for checking indoor leakage by instructing to continuously read the meter by varying the meter reading period for the digital meter of the customer reviewed by the indoor leakage abnormality symptom review unit,
The customer leak check unit measures the amount of use continuously in units of 1 to 10 minutes based on the time of day when the frequency of use is the lowest, and there is 0 (no use) or the minimum flow rate (starting flow rate * unit time) ) If there is, it is confirmed that it is not a leak, and if the metered usage exceeds the minimum flow rate by re-inspecting it based on the time zone where the frequency of use is the lowest for two days, it is confirmed as a leak of the customer. In claim 1,
The leak management module
Smart metering-based indoor leak detection system, characterized in that it further comprises a customer leak notification unit for notifying the indoor leak status to the customer identified as indoor leak by the customer leak confirmation unit. In paragraph 2,
The indoor leakage abnormality review unit is based on Big Data, based on the life pattern of the minimum amount of water use during the dawn time, the pattern based on the previous use as an increase compared to the amount used in the last month or last week, and the pattern based on the surrounding usage as an increase compared to the same level of water consumption. Smart metering-based indoor leak detection system, characterized in that by analyzing and reviewing signs of abnormal indoor leaks of customers. In paragraph 2,
When the indoor leakage abnormality symptom review unit is not detected as less than the starting flow rate for a certain period of time, the indoor leakage detection system based on smart metering analyzes as an indoor leakage indication and examines the indoor leakage abnormality indication of the customer. delete In paragraph 2,
The digital meter is a smart metering-based indoor leak detection system, characterized in that having a continuous use alarm function and a function of measuring the amount of water used in units of 0.0001㎥ and transmitting it to a wireless communication terminal. delete delete delete delete

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