KR101585377B1 - Apparatus and method for remote monitering flow meter data of water supply middle and small block using mobile communication network and high quality buffering technique - Google Patents

Abstract

The present invention relates to a real-time remote monitoring apparatus for data on a water supply medium-small-area flow meter using a mobile communication network and a high-performance buffering technique. The monitoring system comprises a water supply pipe (8) installed in a submerged water pipe (10) A wireless service unit 16 that wirelessly connects to a water supply area business server 20 at an upper part through wireless packet communication via a mobile communication network 18 together with a flow converter 14 for converting data to meter reading in the monitoring unit 12, ); The wireless service unit 16 controls the packet transmission of the real-time flow rate data read from the flow converter 14 to the waterworks area office server 20 in the flow meter data transmission packet 60 at the time of the real- The flow rate data missing due to the channel failure due to the call failure at the time point is buffered in the database 50 as untransmitted flow rate data and the buffered untransmitted flow rate data And a control unit (30) for controlling the flow of data in the flow meter data transmission packet (60) to be sent to the waterworks area business establishment server (20). The waterworks area establishment server (20) And when it is received, using the measurement time information of the received flow data, All.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a real-time remote monitoring device and method for real-time remote monitoring of data in a water supply small-medium area flow meter using a mobile communication network and an advanced function buffering method.

The present invention relates to a water supply flow rate monitoring system, and more particularly, to an apparatus and a method for collecting and remotely monitoring water flow meter data of a water supply small, medium, and large area flow rate accurately, quickly and efficiently by using a mobile communication network and a high performance buffering technique.

In general, the leakage phenomenon occurring in the water supply pipe network causes not only the loss of water resources but also the necessity of the additional pressurization facility due to the pressure loss and the weakening of the soil around the leaked pipe line, thereby making maintenance of the pipe network difficult and causing serious economic loss .

Therefore, in order to maintain efficient water supply and water supply network, most of the regions in Korea are divided into zones (large zone, middle zone, and small zone), and a block system for monitoring the flow rate of each block is adopted . In other words, the district monitoring system divides the transmission, distribution, and supply areas of the city, which are complicatedly formed, into zones of grid-like blocks by elevation and topography, so that the flow of the water flowing in and out is transmitted in one direction, The flowmeter and water pressure meter are installed in each divided area to monitor the water pressure and the flow rate at the control station so that the leakage can be prevented actively and leakage can be prevented to improve the flow rate. Maintenance. Therefore, the 1% improvement in the water flow rate in the maintenance of the water network is almost 100 million won, which is a very important issue.

Waterworks For the maintenance of the water network, the flow values of the pumping station, the reservoir or the large area flowmeter are collected at the facility station through a public leased line. The flow data and various information of the water purification plant are collected through a collection server of the waterworks headquarters with the waterworks integration database through the internal network such as the administrative computer network.

In many cases, flowmeters in Jung-gu or small-scale stations are installed in a flow meter room covered with a manhole on a pavement, or installed in an alley or an outlet, so an on-site meter team dispatches to a manhole where a flow meter is located, Most cases. It requires a circle of 2 to 3 persons and a vehicle and equipments. In each site, about 30 ~ 60 small and medium sized areas are visited by the metrology institute and metrology equipment And the inspection is carried out.

The meter probe returns to the waterworks area and collects and processes the meter meter data and transmits the processed meter data to the waterworks headquarters via e-mail. The waterworks headquarters receives the flowmeter data from all local business establishments and collects them into the integrated waterworks database. In practice, it is possible to collect flowmeter data of the waterworks of small and medium area every month.

Therefore, if a method of collecting and meter reading that can receive flow meter data of the small and medium area of the water supply more quickly and accurately is sought, it will be able to get a great response from the person concerned.

No. 10-082118 entitled "Flow Meter Device for Flow Rate Monitoring Block System"

Accordingly, an object of the present invention is to provide a water supply system and a water supply system using a mobile communication network and a high-performance buffering technique, which enable a water supply meter checker to collect and meter data of a small- And a data real-time remote monitoring apparatus and method.

Another object of the present invention is to provide a water supply system capable of promptly recognizing and coping with the occurrence of transient overflows (leakage, tube rupture) in a water supply small and medium area, The present invention provides a real-time remote monitoring apparatus and method for data of a water supply medium-small-area flow meter using a mobile communication network capable of monitoring flow data with a high-performance buffering technique.

In accordance with the present invention, there is provided a real-time remote monitoring apparatus for data on a water supply medium-small-area flowmeter, comprising: a mobile communication network; a flow meter having a data collection process, (10) connected to the flow meter (8) installed in the underground water pipe (10) of the water supply small and medium area by the ground communication line (9) And a wireless service unit (16) wirelessly connecting to a water supply area business office server (20) at an upper part through wireless packet communication via a mobile communication network (18) together with a flow converter (14)

The wireless service unit (16) comprises:

A memory 38 having a graphical representation of the flow data, a flow data collection report and a data collection process for leakage prevention in a small to medium sized water supply, and a movement corresponding to the flow meter ID required for wireless packet transmission via the mobile communication network 18 Database for storing various report processing information for analyzing the flow trent pattern for occurrence of temporary excess flow (leakage, tube rupture) occurrence and leakage area discrimination, A wireless unit 33 for wirelessly transmitting the packet data through the mobile communication network 18 in a flow meter data transmission packet format and a real time flow data read from the flow converter 14 at a real time reporting period to a flowmeter data transmission packet 60 ) To control the packet transmission to the water service area business office server 20, and according to the channel unassignment due to the call failure at the time of the real time reporting period And stores the missing flow rate data in the database 50 as untransmitted flow rate data. The buffered untransmitted flow rate data is stored in the flowmeter data transmission packet 60, And a control unit 30 for controlling packet transmission to the office server 20,

Wherein the waterworks area establishment server (20) is configured to assemble and arrange among the previously received real time flow data using the measurement time information of the received flow data when the missing transmission data is missing. It is a real-time remote monitoring device for data of waterworks medium-sized area flowmeter using communication network and high-performance buffering technique.

The control unit 30 of the wireless service unit 16 calculates the leaked area alarm information or the reference weekly flow rate trend pattern and the weekly flow rate trend pattern obtained by comparing and analyzing the nighttime flow pattern of the day of the week and the nighttime minimum flow pattern of the corresponding day (Leakage and tube rupture) occurrence information obtained as a result of comparison to the flow meter data transmission packet 60 as report processing data to send a packet to the water service area business office server 20 .

In the present invention, the flow meter data transmission packet 60 is divided into a header section 62 and a payload section 64. The payload section 64 includes a real time data field 66 for loading real time flow data, A machining data field 68 for loading the data and a missing data field 70 for loading the untransmitted flow data missing in the call failure.

The mobile communication network 18 used in the present invention is one of a WiBro communication network and a 3G communication network.

The database 50 of the wireless service unit 16 includes a flow meter ID corresponding MIN information storage unit 54 for storing the mobile terminal identification unique information corresponding to the flow meter ID required for wireless packet transmission through the mobile communication network 18 A real time flow rate data collection unit 42 for storing real time flow rate data collected in units of seconds from the flow rate converter 14, And a graphical representation in the waterworks area business office server 20 at the upper part, and a reference weekly flow trend pattern by analyzing daily and weekly days using the accumulated flow data collected and collected at night, A data storage section 44 for graphic and collecting reports for storing processing data and graphic information including a minimum nighttime flow pattern, A reference weekly flow trend pattern storage section 46 for storing the reference weekly flow trend pattern extracted by the analysis of the reference weekly flow pattern, a minimum weekly flow pattern storing a minimum flow pattern at night according to day of the week, And a pattern storage unit (48).

In another aspect of the present invention, there is provided a real-time remote monitoring method for data on a water supply medium-small-area flow meter, comprising the steps of: monitoring a ground monitoring point (12) connected to a flow meter (8) installed in an underground water pipe (10) And a wireless service unit 16 for wirelessly connecting to the upper water supply area business office server 20 through wireless packet communication via the mobile communication network 18 together with the flow converter 14 for converting data into meter reading The wireless service unit 16 receives a homogeneous road channel assignment through the mobile communication network 18 using the mobile terminal identification unique information corresponding to the flow meter ID at the time of real-time reporting of the flow data, The controller 16 loads the real-time flow rate data read from the flow converter 14 at the time of the real-time report of the flow rate data data into the flowmeter data transmission packet 60, The wireless service unit 16 transmits a wireless packet to the local office server 20 and the wireless service unit 16 receives a call attempt again until the next real time reporting period The wireless service unit 16 receives the channel allocation and transmits the real-time flow rate data to the waterworks area business office server 20 in a wireless packet transmission process. In response to the call attempt, The wireless service unit 16 transmits the real-time flow data read from the flow converter 14 to the mobile station 10 at the time of the real-time reporting period, The wireless service unit 16 avoids the real-time reporting period and stores it in the local data storage unit 52, Transmitting the flow rate data to the waterworks area office server 20 by placing the flow rate data in the flow meter data transmission packet 60 and the waterworks area office server 20 transmitting the flow meter data transmission packet 60 through the mobile communication network 18, And real time monitoring is performed by reading the real-time flow rate data stored in the flowmeter data transmission packet 600. When the non-transmitted flow rate data is received wirelessly in the flowmeter data transmission packet 600, And then performing assembly and alignment of the flowmeter data to the mobile communication network using the high performance buffering technique.

The present invention utilizes a mobile communication network such as a WiBro or a 3G (Generation) communication network to collect and meter flowmeter data in a water supply small and medium area, and an initial business fee for installation of communication equipment such as a wireless service unit (WSU) The meter reading method is influenced by the environment, there is a meter reading disruption according to human condition, and compared with the labor cost, vehicle maintenance cost and facility maintenance cost for meter reading, the cost is saved in the long run and maintenance is excellent. It is possible to constantly monitor the flow data of the small and medium area of the waterworks where it can be confirmed.

In addition, the present invention can collect and remotely monitor the flowmeter data of the small and medium area of the water supply in real time regardless of the bad environment such as the location of the flowmeter in the water supply small and medium area and the temporary excessive flow rate ) Rapidly recognizes the occurrence situation or the leaked area and remotely transmits it to the super administrator so that it can cope quickly. Further, the present invention is advantageous in that, when communication is lost after communication disruption due to the use of the mobile communication network, the flow data is transmitted in real time, and the missing flow data in the small and medium area of the water supply system is transmitted without loss have.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a schematic block diagram for real-time remote monitoring of water quality data for small- and medium-sized waterworks according to an embodiment of the present invention;
FIG. 2 is a block diagram showing a wireless service unit (WSU) installed in a field monitoring unit provided near a flowmeter in a water supply small and medium area for wireless communication using a mobile communication network to a water service area business server according to an embodiment of the present invention;
3 is a diagram for explaining a wireless network connection of a wireless service unit for water management of the present invention;
4 is a detailed block diagram of a wireless service unit of the present invention,
FIG. 5 is a control flow chart in a wireless service unit according to the present invention,
FIG. 6 and FIG. 7 are graphs of characteristic graphs which are utilized in a water service area office server by using flow trend patterns of corresponding small and medium areas,
FIG. 8 is a report form in which a report function reports a water service area server to a water service head server.
9 is a flow meter data transmission packet format diagram for packet transmission in a wireless service unit of a field monitoring unit using a mobile communication network in a 3G network environment or a WiBro environment according to the present invention;
10 is a specific example of the data field of the flowmeter data transmission packet of FIG. 9,
FIGS. 11A to 11D are control flow diagrams for packet transmission of flow rate data in a wireless service unit of a field monitoring unit according to an embodiment of the present invention;
FIG. 12 is a flowchart illustrating a flow of a flow meter data transmission packet transmitted from a wireless service unit of a field monitoring unit in FIG. 11A to FIG.

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

In the present invention, flow meter data is collected and measured manually by using a mobile communication network such as a wireless broadband internet (Wirbro) or a third generation (3G) mobile communication network, It can be remotely monitored in real time, and realizes low cost maintenance as well as no missing data.

The wireless broadband Internet, commonly referred to as "WiBro (Wireless Broadband Internet)," is the ability to use the Internet anytime and anywhere, just like the 3G network for mobile phones and smartphones. Theoretically, the maximum transmission rate is 10 Mbps, the maximum transmission distance is 1 km, and it can be used while moving at a speed of 120 km / h. The average speed of wireless broadband internet is less than 100Mbps high speed internet, but it is faster than 3G communication network such as smart phone. There is no big obstacle to using the netbook or laptop with the internet. As of March 2, 2011, wireless broadband Internet in Korea is available in 82 major cities including Seoul, the metropolitan area, and five metropolitan cities, and seven major expressways including the Kyungbu, Central and West coast.

Using this wireless broadband internet, the present invention continuously monitors the flowmeter data of the waterworks small and medium area to monitor the waterworks small and medium area smoothly.

In addition, the present invention monitors the flowmeter data of the waterworks small and medium area at all times by the mobile communication network using the 3G communication network which is provided in the area where the wireless broadband Internet service (WiBro) is not provided, do.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a schematic block diagram for real-time remote monitoring of water quality data for small- and medium-sized waterworks according to an embodiment of the present invention.

1, the flow meter 8 installed in the underground water line 10 in the water supply small and medium area is mainly located in the flow meter room 6 below the manhole 4 on the road 2.

In the present invention, in order to solve the difficulty that the meter reading unit goes directly to the flow meter 8 below the manhole 4, a field inspection board 12 is installed on the ground where the meter reading like the delivery around the road is secure, The flow rate converter 14 for receiving the flow rate data of the flow meter 8 in real time is connected to the field monitoring unit 12 through a communication line 9 and a flow meter 8 installed in the ground below the manhole 4. [ Respectively.

In this case, the meter reading source approaches only the field monitoring unit 12 provided at a position capable of meter reading without opening the manhole 4 in which the flow meter 8 is installed. If necessary, the flow meter 14 is provided with a meter reading device So that the inspection of the corresponding flowmeter 8 in the small and medium area is facilitated.

The flow rate converter 14 is a device for converting the flow rate information measured by the flow rate meter 8 into a data compatible with the meter reading device. The flow rate data of the flow rate meter 8 Flow rate, pressure information, etc.) and remote meter reading can be done.

In the present invention, a wireless service unit (WSU) 16 for monitoring the flow meter data of the water supply medium-area flow meter 8 at all times is provided in the field monitoring unit 12 using the mobile communication network 18 The wireless service unit 16 is configured to be directly connected to the flow converter 14.

The wireless service unit (WSU) 16 of the present invention is capable of performing data communication with the upper water supply area business office server 20 through a mobile communication network 18 connection such as a WiBro or 3G communication network, The present invention realizes almost no data loss in the water service area business server 20 by using the high-performance buffering technique according to the present invention while using the mobile communication network 18 service, which is much lower in cost per line.

One example of the required cost is about 50,000 won per line when using the existing private line, while the wireless service unit system of the present invention requires about 30,000 won per line due to the use of the mobile communication network 18, It is much cheaper. In addition, the wireless service unit system of the present invention can reduce the cost remarkably compared with the conventional one because the communication charge for using the cellular network (mobile communication network) is about 5,000 won per month.

The wireless service unit system of the present invention uses the mobile communication network 18 of an existing mobile communication network provider such as KT as it is, and there is no additional communication construction cost, and the communication surge voltage In addition, leakage free software is provided free of charge, so that it can quickly recognize and respond to occurrences such as leaks and pipe ruptures in the corresponding small and medium waterworks area.

However, the wireless service unit (WSU) 16 according to the present invention is connected to a mobile communication network using a wireless broadband Internet service (WiBro) or a third generation mobile communication network (3G) (WSU) 16 has a MIN (Mobile Identification Number) as a terminal identification unique number corresponding to the mobile terminal.

Since the connection with the base station is performed in a radio environment unlike the wired exchange network, the radio service unit 16, such as the mobile terminal, which is given a terminal identification unique number (MIN) Communication disturbance phenomenon that can not be a call service due to the influence of the surrounding environment and the power control problem between the base station and the terminal during the propagation of the electric wave or the area may occur from time to time.

In the present invention, real-time monitoring of the flow rate data can be continuously performed even if such a call communication disorder phenomenon occasionally occurs, and it is possible to continuously monitor the flow rate data in the upper water district office server 20 or the water supply head server 24 For the overall monitoring and management of the flow meters, the restoration of the flow data missing due to the communication failure is also implemented in the waterworks area office server 20 together.

For this, in the present invention, the wireless service unit 16 of the field monitoring unit 12 performs real-time packet transmission of the flow rate data in accordance with the flow rate data reporting period (for example, 15 seconds to 3 minutes) In addition, the flow data that is missing due to the communication failure is buffered separately, and after the communication failure is restored, the packet transmission is performed. In addition, the server 20 of the waterworks area office at the upper part can remotely monitor the real time flow meter data, Flow data can also be collected between real-time reporting periods and assembled into the insert, allowing remote monitoring of each flow meter and overall flow rate management to be easily accomplished.

2, in order to perform wireless packet communication using the water service area business server 20 and the mobile communication network 18, a field monitoring unit 12 provided near the flow meter 8 in the water supply small- And a service unit (WSU) 16 are installed.

The wireless service unit 16 mounted on the field supervisor 12 with the flow converter 14 is communicatively connected to the flow converter 14 via a communication interface such as RS232C or RS485 and is connected to the wireless modem 26, And is wirelessly connected to a regional office server 20 connected to the compatible Ethernet 22 through a mobile communication network 18 such as a WiBro or a 3G communication network. Also, it can perform wireless communication with a mobile terminal (21 in Fig. 1) possessed by an administrator.

Each water service area office is responsible for a number of small and medium area flow meters 8 in the area and provides data collection for real time remote monitoring of small and medium area flow rate data through the mobile communication network 18 with the wireless service unit 16 of the present invention. And a waterworks area business establishment server 20 on which a process is installed.

Each waterworks area business establishment server 20 is communicatively connected between the upper waterworks head office server 24 that is integratedly managed as shown in FIG. 1 or between Ethernet networks such as an administrative network. According to the present invention, when the local office server 20 collects the flow rate data of the waterworks medium-area flow meter 8 in real time via the Ethernet 22 connected to the mobile communication network 18, And reports it to the water supply head server 24 at the upper part via the Ethernet 22. Then, the waterworks headquarters server 24 can collect and manage the flow data. In other words, it is possible to acquire the flow rate and manage the flow rate using the flow data of all the small and medium areas under the control.

The wireless service unit 16 connected to the field transducer 14 and mounted on the field monitor 12 according to the present invention is capable of wireless communication using the mobile communication network 18 without being limited by time or space It is possible to establish a wireless connection with a mobile terminal (21 of FIG. 1) as shown in FIG. 3, for example, a smart phone 21a, a printer 21b, a notebook computer 21c and a data storage 22d.

4 is a detailed block diagram of the wireless service unit 16 of the present invention mounted on the field supervisory board 12. As shown in FIG.

The wireless service unit 16 of the present invention is assigned a MIN (Mobile Identification Number), which is a unique identification number of a mobile terminal corresponding to the flow meter, such as a mobile terminal such as a mobile phone, and performs only data communication without a voice call function .

The wireless service unit 16 of the present invention collects and inspects the flow rate data of the small and medium area flow meter 8 and displays the flow rate data of the real time flow rate data using the mobile communication network 18 including the mobile communication network A control unit 30 for performing overall control for wireless reporting utilizing a mobile communication network without data loss at the time of communication interruption using radio transmission and a high performance buffering scheme, a flow converter 14 installed in the field monitoring unit 12, A wireless unit 33 for interfacing with the wireless modem 26 and transmitting wireless packets through the mobile communication network 18 in a flow meter data transmission packet format, (34) and a status display (36). Also, a communication port for connection with an external device such as a notebook computer is also provided, and the mobile terminal 21 as shown in FIG. 2 is wirelessly connected via the wireless modem 26.

The wireless service unit 16 of the present invention also includes a memory 38 and a database 50 as a storage unit according to the present invention.

The memory 38 stores a data collection process with a data collection process 40 that includes user defined functions including comparisons, arithmetic, and alarms for graphical and collection report basic functionality and leak protection systems. The data collection process 40 mapped to the memory 38 can be implemented by a program using a HMI (Human Machine Interface) tool or the like. The data collection process 40 is performed by the wireless service unit 16, Are simultaneously programmed. The data collection process 40 may be implemented such that graphic creation or data processing for collective report generation is performed as a basic function, and a leakage prevention system including comparison, calculation, and alarm may be selectively implemented as a user defined function .

The database 50 of the wireless service unit 16 is used to collect and meter flow data of the small and medium area flow meter 8 and to allow the water supply area business server 20 at the upper part to confirm and alarm the flow pattern and trends accordingly And it is utilized in processing for analysis and generation of data for upper reporting.

The database 50 includes a MIN information storage unit 52 for storing a MIN (Mobile Identification Number), which is a unique identification number of a mobile station assigned to the corresponding flow meter ID, A real time flow rate data collection unit 42 for storing real time flow rate data collected in units of seconds from the flow rate converter 14, It is used for graphical representation and collection report generation at the establishment server 20, and includes a reference weekly flow trend pattern by analyzing daily and weekly days using accumulated flow data, a nighttime flow rate of the day of the week, A graphical and collective report data storage unit 44 for storing processing data and graphic information, And a flow rate based on weekly trend pattern storage unit 46, and a day and night minimum flow pattern storage section 48 for storing the day of the week night minimum flow pattern extracted by the analysis each day of the week on a weekly to store the trend pattern.

In the wireless service unit 16, the status display unit 36 is composed of a lower apparatus operation status lamp, an upper apparatus operation status lamp, an error display lamp, a power indicator lamp, and the like.

In the present invention, since the wireless service unit 16 is mounted on the field monitoring unit 12 and the monitoring function or the alarm function is useless, the wireless service unit 16 can perform graphical monitoring, leak prediction alarm, And causes the mobile communication network 18 such as the 3G communication network to transmit and store the data to the water service area business server 20 without dropping the flow data even when the wireless communication such as call drop is disconnected.

The radio service unit 16 of the present invention having the above-described configuration is configured to transmit the flow rate data of the flow meter 8 to the mobile communication network (for example, 18 in real time. That is, the wireless service unit 16 adapts the flow data read at the preset real-time reporting period to the flowmeter data transmission packet format according to the present invention and performs the data collection process using the mobile communication network 18 via the wireless modem 26 And wirelessly reports it to the server 20 of the waterworks having the local business.

In addition, the wireless service unit 16 of the present invention wirelessly transmits the flow data in real time, and real-time collection is performed using the data collection process 40. The wireless service unit 16 analyzes the flow data by daily and weekly days using the accumulated flow data The reference weekly flow trend pattern and the nighttime minimum flow pattern for each day are stored and stored in the reference weekly flow pattern storage unit 46 and the nighttime minimum flow pattern storage unit 48 of the database 50, respectively.

FIG. 5 is a control flowchart in the wireless service unit 16 according to the present invention mounted on the field monitoring unit 12, and FIGS. 6 and 7 illustrate a flow chart of the flow rate trend pattern in the water service area office server 20 Which is a characteristic graph drawing utilized.

The wireless service unit 16 of the field monitoring unit 12 collects the flow data (integration, instantaneous flow rate, pressure information, etc.) from the corresponding flowmeter 8 of the small and medium area in real time via the flow converter 14, Time flow data collection unit 42 (step 100 of FIG. 5). An example of the real-time collection may be a cycle of seconds, for example, 15 seconds.

 The wireless service unit 16 reports the flow rate data to the flow meter data transmission packet 60 format every reporting period (for example, 15 seconds to 3 minutes) using the mobile communication network 18 5, step 100). When reporting the flow rate data, it is also possible to analyze not only the real-time flow rate data but also the data stored in the wireless service unit 16 and processed according to the stored reference weekly flow trend pattern or night minimum flow pattern, graphic function or report function .

The waterworks flow rate data is transmitted from the wireless service unit 16 of the field monitoring unit 12 to the waterworks area establishment 20 in accordance with the flow meter data transmission packet 60 format using the mobile communication network 18 of a mobile communication network such as WiBro or 3G The wireless reporting format description and its detailed operation description will be described later with reference to Figs.

5, the radio service unit 16 collects the upper report on the real-time flow rate data and the real-time flow rate data in the real-time flow rate data collection unit 42 of the database 50, (Step 102 of FIG. 5), and also accumulates weekly collected data (step 104 of FIG. 5).

The wireless service unit 16 mounted on the field monitoring unit 12 analyzes and identifies the flow trend pattern using the collected data (daily collection data, weekly collected data, etc.) accumulated in the database 50, Pattern and night minimum flow pattern are stored and stored in the reference weekly flow trend pattern storage unit 46 and the night minimum flow pattern storage unit 48 (step 106 of FIG. 5). The night minimum flow pattern can be extracted by averaging a plurality of night minimum flow values, for example, five to six.

Then, the wireless service unit 16 of the present invention also determines whether or not there is a leakage estimated area using the extracted minimum nighttime flow pattern, and generates alarm information therefrom (step 108 in FIG. 5). The nighttime flow rate pattern of the day of the week is compared with the nighttime minimum flow rate pattern of the corresponding day of the week to determine whether or not the zone is predicted to leak, and alarm information for the predicted leak zone is generated. The leak alarm zone alarm information is wirelessly reported to the upper waterworks area business office server 20 by using the flow meter data transmission packet 60 format immediately after occurrence of the process data cycle report or the event situation occurring every one hour interval.

In addition, the wireless service unit 16 of the present invention compares the pre-stored reference weekly flow trend pattern with the preliminary flow trend pattern, specifically compares and analyzes the same day flow trend patterns to grasp the occurrence of temporary excessive flow (leakage, torn) So that the piping accident situation in the corresponding small and medium area is predicted and detected (step 110 in FIG. 5). The piping accident situation information of the corresponding small and medium area is also reported to the server 20 of the water supply area business office 20 at the time of reporting the process data cycle performed every hour or immediately after occurrence of an event situation.

FIG. 6 and FIG. 7 are characteristic graphs that are utilized by the server 20 of the waterworks area business office using the flow trend pattern of the corresponding small and medium area.

The waterworks area business office server 20 has a database 20a for collecting and storing flow data of the corresponding small and medium waterworks area received from each wireless service unit 16 via the mobile communication network 18 and also includes a data collection process Graphic monitoring such as that shown in FIG. 6 or 7 can be performed by using the graphics equipped with the basic functions, the collection report function, and the leakage preventing system function.

FIG. 6 is a graph graphically showing 10-day collected data received from the wireless service unit 16, and the collected data for one day can also be viewed as a detailed graph of time through real-time data collection analysis.

As shown in Fig. 6, the corresponding small and medium area is Daegu Metropolitan City's Gamdang-dong area, and it can be understood that the pattern of the flow rate of the corresponding area (geomdan dong) can be grasped at a glance through trends. Since the area is located in the Geomdan Industrial Complex, it can be confirmed that the amount of water used is sharply reduced on weekends.

FIG. 7 is a graphical representation of the leak prediction area alarm information wirelessly transmitted from the wireless service unit 16 of the field monitoring unit 12 or piping accident state prediction information of the corresponding small / FIG.

The manager of the water service area business site server 20 can select the relevant small and medium area and designate the period to inquire. For example, the flow rate tendency on Monday and the flow rate tendency on Monday this month can be compared and analyzed by a graph. Patterns can also be found visually through monitoring.

In addition, the water supply area business office server 20 may generate an alarm for the leaked area by comparing and analyzing the night minimum flow rate of the day of the week at predetermined intervals using the collected data.

In addition, the waterworks area business office server 20 can generate a report similar to the document format (e.g., Excel) used in the waterworks headquarters using the report function and the data, and report the data to the waterworks head office server 24 through the Ethernet 22 . FIG. 8 shows an example of the above report form.

9 is a flow meter data transmission packet format for packet transmission from a wireless service unit 16 of a field monitoring unit 12 to a water service area business server 20 using a mobile communication network 18 of a 3G network environment or a WiBro environment according to the present invention. And Fig. 10 is a specific configuration diagram of the data field of the flow meter data transmission packet of Fig.

9, a flow meter data transmission packet 60 used for packet transmission according to the present invention is packet data composed of 512 bytes and includes a header section 62 and a payload section 64, .

In FIG. 9, the header section 62 includes a missing flag bit (not shown) for indicating that untransmitted data (missing part) is transmitted in the payload 64 according to the present invention due to a communication disconnection state due to a radio call failure or a call failure F1), and a processing flag bit F2 for indicating that the alarm information for the graphic or collection report or the leakage alarm is predicted, or the piping accident situation prediction detection information for the corresponding small / medium area is loaded.

In FIG. 9, the payload section 64 of the flowmeter data transmission packet 60 includes a real time data field 66 for loading real time flow data according to the present invention, A machining data field 68 for storing machining data such as piping accident situation prediction information in a medium and small area and a missing data field 70 for loading missing data that has not yet been transmitted due to a communication interruption due to radio call failure or call failure ).

10 shows an example of the specific configuration of the real-time data field 66 of the flowmeter data transmission packet 60 of Fig. 9, and includes a section name, a database name, a flow meter name, a measurement date, a measurement time, Unit, measured static acid, measured static acid unit, measured reverse acid, measured reverse acid unit, measured pressure, measured pressure unit, and so on.

11A to 11D are control flow diagrams for packet transmission of flow rate data through the mobile communication network 18 in the wireless service unit 16 of the field monitoring unit 12 according to the embodiment of the present invention.

11A is a control flowchart when a flowmeter data transmission packet from the wireless service unit 16 of the field monitoring unit 12 to the waterworks area business office server 20 is normally wirelessly transmitted and FIG. 12 is a flowchart showing a routine flow when a call failure occurs when a flowmeter data transmission packet 60 is transmitted from the wireless service unit 16 to the waterworks area business office server 20. FIG. And a flow meter data transmission packet from the wireless service unit (16) of the water supply system (12) to the waterworks area establishment server (20). 11D is a control flowchart in the wireless service unit 16 of the field surveillance unit 12 in a report processing data transmission situation in which collecting and reporting a temporary overflow (leakage or tube rupture), a leakage expectation zone alarm, and the like is collected and reported.

First, referring to FIG. 11A, when the communication using the mobile communication network 18 such as the WiBro or the 3G communication network is normal, the communication between the wireless service unit 16 of the field monitoring unit 12 and the waterworks area office server 20, The real-time remote monitoring of the mobile terminal is performed as follows.

The wireless service unit 16 of the field monitoring unit 12 sets a real time reporting period. The real-time reporting period can be set by the administrator through the input unit 34 of the field monitoring unit 12 as a period of real-time reporting of the flow data to the upper water supply area business office server 20, And can also be set in the terminal 21 or the waterworks area business office server 20. In the embodiment of the present invention, the real-time reporting period is selected and set within the range of 15 seconds to 3 minutes (step 100 of FIG. 11A).

The wireless service unit 16 then collects and temporarily stores the flow rate data of the corresponding small and medium area flow meter 8 in real time (for example, 15 seconds) through the flow converter 14 (step 102 of FIG. 11A).

11A), the radio service unit 16 transmits the flow rate data to the flow rate converter (not shown) at the reporting time point in order to transmit only the flow rate data collected at the reporting cycle time 14) (step 105 in Fig. 11A).

The wireless service unit 16 then makes a call attempt with MIN (Mobile Identification Number) information corresponding to the flow meter ID in step 106 of FIG. 11A. The MIN information is mobile terminal unique identification information allocated to the flow meter 8.

After a call attempt with MIN (Mobile Identification Number) information, the radio service unit 16 transmits a channel assignment between the radio service unit 16 and the waterworks area establishment server 20 from the base station control station in the mobile communication network 18 (Step 108 of FIG. 11A).

If the channel allocation is not performed, the call disruption routine is performed in preparation for the communication disconnection. If the channel allocation is normally performed, the real time flow data read at the reporting period collected at step 105 of FIG. 11A is transmitted to the flowmeter data transmission packet Real-time data field 66 of the mobile station 60 in a format as shown in FIG. 10, and performs packet transmission (step 110 of FIG. 11A).

Next, referring to FIG. 11B, when the wireless communication using the mobile communication network 18 such as the WiBro or the 3G communication network is a situation such as a call failure or a call interruption, As follows.

If the channel is not allocated in step 108 of FIG. 11A, the radio service unit 16 enters the call disturbance routine of FIG. 11B and makes a call attempt again before the next real time reporting period (3 minutes) step).

The radio service unit 16 judges whether there is a channel allocation according to the call attempt again at step 114 of FIG. 11B. If the channel assignment is immediately made, the real-time flow data read at the reporting period is transmitted to the flowmeter data transmission packet The real-time data field 66 of the mobile station 60 in the format shown in FIG. 10 in accordance with the format, and performs packet transmission (step 118 in FIG. 11B).

However, if the channel allocation according to the call attempt again does not occur immediately before the next real time reporting period, the radio service unit 16 proceeds to step 116 of FIG. 11B to transmit the local data to the local data storage unit 54 in the database 50 of the radio service unit 16 And the flow rate data is transmitted to the controller. The untransmitted flow data stored in the local data storage unit 54 includes a measurement date and a measurement time as shown in the real time data field 66 of FIG. 10, (54).

 The local data storage unit 54 of the database 50 continuously stores the flow rate data that is not continuously transmitted during the communication disconnection period.

The untransmitted flow rate data stored in the local data storage unit 54 will be transmitted again after the call disconnection is canceled after the communication disconnection is canceled but will be transmitted without any trouble to the real time transmission of the flow rate data according to the present invention, The received waterworks area business office server 20 measures the missing untransmitted flow data so that it can be assembled normally with the normally received flow data. The control operation of the waterworks area business office server 20 will be described in more detail with reference to FIG.

Next, with reference to FIG. 11C, a procedure of performing a process in the wireless service unit 16 of the field monitoring unit 12 in a situation where communication is lost is described as follows.

11C, the radio service unit 16 checks whether there is untransmitted flow data in the local data storage unit 52 of the database 50 (FIG. 11C Step 122 of FIG.

If there is untransmitted flow data in the local data storage unit 54, it is necessary to transmit the untransmitted flow data. The transmission of the untransmitted flow data should prevent the real time transmission of the flow data from being interrupted. For this, in the present invention, the real-time flow rate data is transmitted at the time of the real-time reporting period and the missing transmission flow rate data is transmitted during the period between the real-time report periods.

In the present invention, if there is untransmitted flow data (step 122 of FIG. 11C), then the wireless service unit 16 determines whether it is a real time reporting period (step 124 of FIG.

The wireless service unit 16 performs steps 126 through 130 of FIG. 11C to transmit only the real-time flow data read by the flow converter 14 at the reporting cycle time into the real-time data field 60 of the flow meter data transmission packet 60 (66) and transmits the packet to the water service area office server (20).

11C), the wireless service unit 16 proceeds to step 126 of FIG. 11C and selects only the flow rate data collected from the flow rate converter 14 at the reporting cycle (FIG. 11C (Step 125 of FIG. 11C). Next, a call attempt is made using MIN (Mobile Identification Number) information corresponding to the flow meter ID (step 126 of FIG. The wireless service unit 16 transmits the real time flow data read at the reporting period to the flow meter data of FIG. 9 (step < RTI ID = 0.0 > The format is matched to the real time data field 66 of the transmission packet 60, and the packet is transmitted to the water service area business server 24 in the same manner as in FIG. 10 (step 130 in FIG. 11C).

On the other hand, if it is determined in step 124 of FIG. 11C that the real-time reporting period is not the wireless service unit 16, the wireless service unit 16 performs steps 131 through 136 in FIG. 11C to transmit the missing transmission flow data to the local data storage unit 52 and stores the predetermined amount of transmission in the missing data field 70 of the meter data transmission packet 60 and transmits the packet to the waterworks area business office server 20.

The wireless service unit 16 proceeds to step 131 in FIG. 11C to select the missing transmission flow data missing from the local data storage unit 52 (refer to FIG. 11C) Step 131). Next, a call attempt is made with MIN (Mobile Identification Number) information corresponding to the flowmeter ID (step 132 of FIG. 11C). 11C), the wireless service unit 16 transmits the selected non-transmitted flow data read from the local data storage unit 52 to the mobile station Is loaded into the missing data field 70 of the meter data transmission packet 60 of Figure 9 and at the same time the missing flag bit F1 of the header section 62 is set to the water service area office server 24, (Step 136 of FIG. 11C).

Finally, referring to FIG. 11D, an operation procedure in the wireless service unit 16 of the field supervisory unit 12 in the reporting process data transmission condition for reporting a temporary excessive flow rate such as leakage of water or pipe rupture, As follows.

In step 111 of FIG. 11A, the wireless service unit 16 determines whether there is data for reporting or event generation processing by checking the data storage unit 44 for graphics and collection report of the database 50. FIG.

If there is reporting or event generation data such as a leak or tube rupture, the wireless service unit 16 performs steps 140-146 of FIG. 11D to read the report or event generation data from the database 50, In the processing data field 68 of the transmission packet 60, and transmits the packet to the waterworks area business office server 20.

That is, if there is processing data such as a temporary excessive flow rate such as a leak or a pipe rupture, an alarm for a leaked area, etc., the wireless service unit 16 reads data for reporting processing data (Step 140 of FIG. 11D). Then, a call attempt is made with MIN (Mobile Identification Number) information corresponding to the flow meter ID (step 142 of FIG. 11D). 11D), the wireless service unit 16 transmits the read data to the wireless terminal 10 via the wireless communication unit 10 in the data storage unit 44 for graphics and collection report The selected reporting processing data is loaded into the processing data field 68 of the flow meter data transmission packet 60 of Fig. 9 and at the same time the processing flag bit F2 of the header section 62 is set to & And transmits the packet to the office server 24 (step 146 of FIG. 11D).

Transmission of reporting data can be performed with real-time flow data at the time of the real-time reporting period, but it is preferable to transmit the data while avoiding the real-time reporting period.

5, the wireless service unit 16 drives the data acquisition process 40 and analyzes and stores the data by day, week, and day using the flow data collected and accumulated through the flow converter 14 , The reference weekly flow pattern and the nighttime minimum flow pattern for each day of the week are extracted using the accumulated flow data collected and stored in the reference weekly flow pattern storage unit 46 and the night minimum flow pattern storage unit 48 of the database 50 And a process of storing the data.

11A to 11D, when the wireless transmission of the flowmeter data transmission packet 60 from the wireless service unit 16 of the field monitoring unit 12 is performed, It collects the water flow data of the flow meter and performs remote meter reading and monitoring.

12 is a control flowchart in the waterworks area business office server 20 when the meter data transmission packet 60 transmitted from the wireless service unit 16 of the field monitoring unit 12 is received in Figs. 11A to 11D.

Referring to FIG. 12, the waterworks area establishment server 20 analyzes the flow meter data transmission packet 60 in step 202 of FIG. 12 when the flow meter data transmission packet 60 is received (step 200 of FIG. 12).

First, it is checked in step 204 or 210 in FIG. 12 whether there is a missing flag flag F1 or a processed flag bit F2.

If there is no missing flag bit (F1) or processing flag bit (F2), the waterworks area business server 20 proceeds to step 214 of FIG. 12 to read the real time data field 66 of the flow meter data transmission packet 60, And stores the real-time flow rate data in the real-time flow rate database 20a. The real time flow rate data stored in the own database 20a is used for real time remote monitoring of the flowmeter in the waterworks area business office server 20 (step 208 in FIG. 12).

If there is a missing flag bit F1 in step 204 of FIG. 12, the waterworks area establishment server 20 proceeds to step 206 of FIG. 12 to read the missing data field 70 of the flow meter data transmission packet 60, The untransmitted flow rate data received in the nonvolatile memory 20a is inserted and inserted between the previously stored real time flow rate data using the measurement time information of the untransmitted flow rate data so that it can be assembled into the full flow rate data.

In this case, the waterworks area business office server 20 can monitor the flow data transmitted in each real-time reporting period in real time as well as fill in the missing data that has not been received due to communication disconnection, thereby utilizing a series of accumulated flow data Can be used for overall monitoring and analysis.

If the process flag bit F2 is present in the flowmeter data transmission packet 60 in the determination of step 210 of FIG. 12, the waterworks area establishment server 20 proceeds to step 212 of FIG. 12 to process the flowmeter data transmission packet 60 Reads the data field 68 and stores the report processing data remotely received in its own database 20a.

 In this case, the waterworks area business office server 20 can monitor the flow data of the corresponding flow meter 8 transmitted in each real time period in real time, and can also monitor the flow rate data of the flow data for reporting by the flow meter 8, It is possible to directly obtain the data of the night minimum flow pattern, the graphical representation and the collection report, and to perform the immediate analysis such as the tubular rupture or leakage of the small and medium area to the corresponding flowmeter 8 as shown in FIGS. 6 to 8, will be.

On the other hand, when the flow data is not received in real time in accordance with the real-time reporting period from the corresponding wireless service unit 16 in the waterworks area business office server 20, communication is terminated if communication is not received even after the check- A communication break alarm alarm also occurs so that the administrator can take action.

While the present invention has been described in connection with what is presently considered to be practical exemplary embodiments, it is to be understood that the invention is not limited to the disclosed embodiments. Therefore, the scope of the present invention should not be limited by the described embodiments, but should be determined by the scope of claims and equivalents thereof.

(2) - Road (4) - Manhole
(6) - Flow meter room (8) - Flow meter
(10) - Water pipeline (12) - Field supervision unit
(14) - flow transducer (16) - wireless service unit (WSU)
(18) - Mobile communication network (20) - Local office server
(21) - Mobile Terminal (22) - Ethernet
(24) - Waterworks headquarters server (26) - Wireless modem
(30) - Control section (32) - Communication interface
(34) - Reset section (36) - Status display section
(38) - memory (40) - data collection process
(42) a real-time flow collecting section
(44) a data storage unit for graphic and collection reports
(46) - reference weekly flow trend pattern storage section
(48) - Night minimum flow pattern storage unit
(50) - Database (52) - Local data store
(54) MIN information storage unit corresponding to the meter ID
(60) - Flowmeter data transmission packet (62) - Header section
(64) - payload interval (66) - real time data field
(68) - machining data field (70) - missing data field
(F1) - Missing flag bit (F2) - Processing flag bit

Claims (10)

1. A real-time remote monitoring apparatus for data on a water supply medium-small-area flow meter,
Each of the flow meters (8) of the underground water pipeline (10) in the water supply small and medium sized area where the accessibility of the meter reading source is difficult is installed one by one on-site monitoring boards (12) 12 to the communication line 9,
The field monitoring unit 12 is provided with a flow rate converter 14 and a flow rate converter 14 which convert data to be meterable so that the flow rate data read from the flow rate meter 8 can be used to perform day- Through the analysis, various kinds of processing information are generated for occurrence of temporary excessive flow (leakage, tube rupture) and judgment of leaked area, and wireless packet communication through the mobile communication network 18 is used to transmit the real time And a wireless service unit (16) for transmitting the flow data and the processing information of the flowmeter alone,
A water service area office server for collecting various kinds of processing information related to the flow meter 8 provided in the field monitoring unit 12 provided for each flow meter 8 through the mobile communication network 18 and remotely monitoring the corresponding flow meter in the water supply small and medium area (20)
The wireless service unit (16) in the field monitoring unit (12) comprises:
A memory 38 having a graphical representation of the flow data, a flow data collection report, and a data collection process for preventing water leakage in the water supply medium area,
The mobile terminal identification unique information corresponding to the flow meter ID required for wireless packet transmission through the mobile communication network 18, the untransmitted flow data missing due to the occurrence of a call failure, the occurrence of temporary excessive flow (leakage, tube rupture) A database 50 for storing various types of report processing information for analyzing a flow tent pattern for the flow tent pattern,
A radio unit 33 for wirelessly transmitting real-time flow rate data and reporting processing information to the flowmeter data transmission packet format through the mobile communication network 18,
Real-time flow rate data and reporting processing information read from the flow converter 14 at the time of the real-time reporting period in the flowmeter data transmission packet 60 to control the packet transmission to the waterworks area business office server 20, The flow rate data missing in accordance with the channel unassignment due to the failure is buffered in the database 50 as untransmitted flow rate data and the buffered untransmitted flow rate data and the reporting processing time And a control unit (30) for controlling the flow of information in the flowmeter data transmission packet (60) to be transmitted to the waterworks area business office server (20)
The waterworks area business office server 20 immediately confirms occurrence of excess flow (leakage, tube rupture) in the flowmeter and determination of the leakage area using the reporting processing information of the flowmeter, Wherein the flow rate data is wirelessly received, and when the flow rate data is received wirelessly, the flow rate data of the corresponding flow rate meter is used to compose the received flow rate data among the received real time flow rate data. Data real time remote monitoring device.
The control unit (30) of the wireless service unit (16) in the field monitoring unit (12) installed for each flow meter (8) (Leakage and tube rupture) information obtained by comparing leaked area alarm information or reference weekly flow trend pattern and weekly flow trend pattern obtained by comparing and analyzing the minimum flow pattern, 60) and controls the packet transmission to the server (20) of the waterworks area by using the mobile communication network and the high performance buffering technique.
The method of claim 1, wherein the flow meter data transmission packet (60) is divided into a header section (62) and a payload section (64), wherein the payload section (64) comprises a real time data field (66) And a missing data field (70) for loading untransmitted flow data missing in call disturbance. The mobile communication network and the water service using the high-performance buffering technique are provided. Monitoring device.
5. The real-time remote monitoring device for data of a small-scale water meter in a water supply system using a mobile communication network and a high-performance buffering technique, wherein the mobile communication network is one of a WiBro communication network and a 3G communication network according to any one of claims 1 to 3.
7. The system according to claim 1, wherein the database (50) of the wireless service unit (16)
A flowmeter ID correspondence MIN information storage unit 54 for storing mobile station identification unique information corresponding to a flowmeter ID necessary for wireless packet transmission through the mobile communication network 18,
A local data storage unit 52 for buffering and storing the untransmitted flow rate data missing due to a call failure,
A real time flow rate data collection unit 42 for storing real time flow rate data collected in seconds from the flow rate converter 14,
It is used to generate graphical representation and collection report at the waterworks area business office server (20) at the upper part. The reference weekly flow pattern by analyzing daily and weekly day by using collected accumulated flow data, a nighttime flow rate of the day of the week, A data storage section 44 for graphic and collecting reports for storing processing data and graphic information including a flow pattern,
A reference weekly flow trend pattern storage unit 46 for storing reference weekly flow trend patterns extracted through analysis by day and day of week of the flow data,
And a night minimum flow pattern storage unit (48) for storing the minimum nighttime flow pattern for each day of the week extracted by analyzing the flow data by day and day of the week. Flowmeter data real time remote monitoring device.
A method for real-time remote monitoring of data on waterworks,
Each of the flow meters (8) of the underground water pipeline (10) in the water supply small and medium sized area where the accessibility of the meter reading source is difficult is installed one by one on-site monitoring boards (12) The wireless service unit 16 in the field supervisory unit 12 is connected to the flow meter 8 via the communication line 9 to connect the flow meter data to the flow meter 14 via the flow converter 14, A first step of reading,
Using real-time flow data read from the flowmeter (8), various processing information for temporary overflow (leakage, tube rupture) occurrence and leaked area discrimination are analyzed through day-by-day analysis and weekly comparison analysis of the flowmeter (8) A second process to be performed by the wireless service unit 16 of the monitoring unit 12,
The wireless service unit (16) includes a third step of receiving a homogeneous road channel allocation through the mobile communication network (18) using the mobile terminal identification unique information corresponding to the flow meter ID at the time of real-time report of flow data,
The wireless service unit 16 loads the real-time flow rate data and reporting processing information read from the flow converter 14 at the time of the real-time report of the flow data in the flow meter data transmission packet 60, A fourth step of wireless packet transmission to the base station 20,
The radio service unit 16 performs the call attempt again until the next real time reporting period to receive the channel allocation and transmits the real time flow rate data and the reporting processing information to the water supply system A fifth step of wireless packet transmission to the local office server 20,
The wireless service unit 16 buffers and stores the missing transmission flow data missing in the local data storage unit 52 of the database 50 in accordance with the channel unassignment due to the call failure,
The wireless service unit (16) at the time of restoration from the call disturbance packetizes the real time flow data read from the flow converter (14) and the report processing information at the time of the real time reporting cycle,
The wireless service unit 16 avoids the real-time report cycle time and loads the unprocessed flow data buffered in the local data storage unit 52 and the reporting processing information into the flowmeter data transmission packet 60, An eighth step of wireless packet transmission to the office server 20,
The waterworks area business office server 20 reads real time flow data and reporting processing information in the flow meter data transmission packet 60 through the mobile communication network 18 to perform real time monitoring and at the same time, If it is wirelessly received in the transmission packet 60, it is assembled and sorted among the received real-time flow data by using the measurement time information of the received flow data, and the excess flow rate in the flowmeter And a ninth step of immediately confirming the occurrence of a leakage (tube rupture) and a judgment of a leaked area. The method of real time remote monitoring of data of a small area water meter of a water supply using a mobile communication network and a high performance buffering method.
[7] The method of claim 6, wherein the wireless service unit (16) comprises: a wireless service unit (16) for calculating leaked area alarm information or a reference weekly flow trend pattern obtained by comparing and analyzing a nighttime minimum flow pattern of the day of the week, A method for real-time remote monitoring of data in a water supply small-medium area flowmeter using a mobile communication network and a high-performance buffering method, characterized in that information on occurrence of temporary overflows (leakage, tube rupture) obtained by comparing flow trend patterns is obtained as processing data.
The method of claim 6 or 7, wherein the real-time reporting period is from 15 seconds to 3 minutes. A method for real-time remote monitoring of data of a water supply medium-sized area flow meter using a mobile communication network and an advanced function buffering technique.
The method of claim 6 or 7, wherein the meter data transmission packet (60) is divided into a header section (62) and a payload section (64), and the payload section (64) comprises a real time data field 66), a machining data field (68) for loading reporting data, and a missing data field (70) for storing untransmitted flow data missing in a call disturbance, and a mobile communication network (70) Real time remote monitoring method of flowmeter data.
The method of claim 6 or 7, wherein the mobile communication network (18) uses one of a WiBro communication network and a 3G communication network.

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