JP2022015525A - Gas leakage detection system - Google Patents

Abstract

To provide a gas leakage detection system capable of locating a gas leakage position.SOLUTION: A gas leakage detection system 300 comprises gas piping, a gas meter 120, and a monitoring center 200. The monitoring center 200 is configured so as to perform the steps of: (A) determining whether there is a gas leakage from the gas piping by comparing a flow rate of a gas flowing through the gas piping with a total sum of flow rates of gases acquired by each gas meter 120 and/or on the basis of a first gas pressure which is a gas pressure detected when there is no flow rate of gases acquired by each gas meter 120; and (B) locating the position at which the gas has leaked on the basis of position information of each gas meter 120 and the first gas pressure detected by each gas meter 120 when the monitoring center determines that the gas leakage has occurred in the step (A).SELECTED DRAWING: Figure 1

Description

The present invention relates to a gas leak detection system.

A gas leak detecting device for detecting a gas leak in a shared pipe of an apartment house or the like is known (see, for example, Patent Document 1). In the gas leak detection device disclosed in Patent Document 1, an electronic source gas meter is provided near the entrance of the common pipe, and the total gas flow rate of the dwelling unit measured by each dwelling unit gas meter is measured by the original gas meter. It is compared with the original gas flow rate, and when the flow rate difference is equal to or more than a predetermined value, it is determined that a gas leak has occurred.

Patent No. 3438955

However, although the gas leak detection device disclosed in Patent Document 1 can detect that a gas leak has occurred in the shared pipe, it cannot identify the location where the gas leak has occurred, and it is still possible. There was room for improvement.

Therefore, an object of the present invention is to provide a gas leak detection system capable of identifying a gas leak location in view of the above-mentioned circumstances.

The gas leak detection system according to the present invention acquires a gas pipe for supplying gas to each dwelling and a gas flow rate in a gas flow path installed in each dwelling and connected to the gas pipe, and obtains the gas flow rate. A gas meter for detecting the gas pressure in the flow path and a monitoring center for collecting the gas flow rate and the gas pressure from each of the gas meters are provided, and the monitoring center includes the flow rate of the gas flowing through the gas pipe. By comparing with the sum of the gas flow rates acquired by each of the gas meters, and / or based on the first gas pressure, which is the gas pressure detected when there is no gas flow rate acquired by each of the gas meters. , The step (A) for determining the presence or absence of the gas leakage from the gas pipe, and the position information of each of the gas meters when it is determined that the gas leakage has occurred in the step (A), and each. Based on the first gas pressure detected by the gas meter, the step (B) of identifying the location where the gas leakage is occurring is configured to be executed.

This makes it possible to identify the location of the gas leak.

According to the gas leak detection system according to the present invention, a gas leak location can be specified.

FIG. 1 is a schematic diagram showing a schematic configuration of a gas leak detection system according to the first embodiment. FIG. 2 is a schematic diagram showing a schematic configuration of a main part in the gas leak detection system shown in FIG. 1. FIG. 3 is a schematic diagram showing a schematic configuration of a gas meter and a monitoring center of the gas leak detection system shown in FIG. 1. FIG. 4 is a flowchart showing an example of the operation of the gas leak detection system according to the first embodiment. FIG. 5 is a flowchart showing another example of the operation of the gas leak detection system according to the first embodiment.

Hereinafter, preferred embodiments of the present invention will be described with reference to the drawings. In the following, the same or corresponding elements are designated by the same reference numerals throughout all the figures, and the overlapping description thereof will be omitted. Further, in all the drawings, the components necessary for explaining the present invention are excerpted and shown, and the drawings of other components may be omitted. Furthermore, the invention is not limited to the following embodiments.

(Embodiment 1)
The gas leak detection system according to the first embodiment acquires gas flow rate in a gas pipe that supplies gas to each dwelling and a gas flow path installed in each dwelling and connected to the gas pipe, and gas. It is equipped with a gas meter that detects the gas pressure in the flow path and a monitoring center that collects the gas flow rate and gas pressure from each gas meter. By comparing with the total flow rate and / or based on the first gas pressure, which is the gas pressure detected when there is no gas flow rate acquired by each gas meter, the presence or absence of gas leakage from the gas pipe is checked. Gas based on the determination step (A) and the position information of each gas meter when it is determined that gas leakage has occurred in the determination step (A) and the first gas pressure detected by each gas meter. It is configured to perform the step (B) of identifying the location where the leak is occurring.

Further, in the gas leak detection system according to the first embodiment, the monitoring center determines that the first gas pressure detected by the gas meter in the step (B) is equal to or less than a preset predetermined gas pressure value. , It may be specified that the vicinity of the place where the gas meter is installed is the place where the gas leak occurs.

Further, in the gas leak detection system according to the first embodiment, the monitoring center divides each dwelling into a plurality of large areas for each of a plurality of dwellings, and in the process (A), gas leaks occur for each large area. It may be configured to specify the gas leak location in the large area where the presence or absence is determined and it is determined in the step (B) that the gas leak has occurred in the step (A).

Further, in the gas leak detection system according to the first embodiment, the monitoring center divides a large area identified as a place where a gas leak occurs into a plurality of medium areas for each of a plurality of residences. In the step (B), gas leakage occurs in the middle area where it is determined in the middle area whether or not there is a gas leak (B1) and in the middle area where it is determined that the gas leak has occurred in the step (B1). It may be configured to execute (B2) to specify the location where the gas is located.

Further, in the gas leak detection system according to the first embodiment, the monitoring center divides each dwelling into a plurality of large areas for each of a plurality of dwellings, and in the step (B), the gas meter in each large area detects. Step of calculating the average value of the first gas pressure and specifying a large area where the calculated average value of the first gas pressure is smaller than other large areas as a place where gas leakage occurs (B3). May be configured to perform.

Further, in the gas leak detection system according to the first embodiment, the monitoring center divides the large area identified as the place where the gas leak occurs into a plurality of medium areas for each of a plurality of residences. In the step (B), the average value of the first gas pressure detected by the gas meter in each middle area is calculated, and the middle area where the calculated average value of the first gas pressure is smaller than the other middle areas is the gas. It may be configured to perform a step (B4) that identifies the location of the leak.

Hereinafter, an example of the gas leak detection system according to the first embodiment will be described in detail with reference to FIGS. 1 to 5.

[Configuration of gas leak detection system]
FIG. 1 is a schematic diagram showing a schematic configuration of a gas leak detection system according to the first embodiment. FIG. 2 is a schematic diagram showing a schematic configuration of a main part in the gas leak detection system shown in FIG. 1.

As shown in FIG. 1, the gas leak detection system 300 according to the first embodiment includes gas pipes 11A and 11B for supplying gas to each residence 100, a gas meter 120 installed in each residence 100, and a monitoring center. It has 200 and. The monitoring center 200 is configured to monitor the gas meter 120 installed in each dwelling 100 belonging to the monitoring area 400.

The monitoring area 400 may be monitored by one monitoring center 200, or may be jointly performed by a plurality of monitoring centers 200. Further, the gas pipe 11A and the gas pipe 11B may be connected by an appropriate pipe.

The monitoring area 400 may be composed of a plurality of (here, two) large areas 500A and 500B. Further, the large areas 500A and 500B may be composed of a plurality of medium areas 70A, 70B and 70N, respectively. Further, each of the plurality of medium areas 70A, 70B, and 70N may be composed of a plurality of small areas.

Here, the configuration of the large area 500A will be described in detail with reference to FIGS. 1 and 2. Since the large area 500B is configured in the same manner as the large area 500A, detailed description thereof will be omitted.

As shown in FIG. 2, a gas pipe 11A is installed in the large area 500A. A first valve 21A and a first gas meter 31A are installed on the upstream side of the gas pipe 11A. The first valve 21A is configured to allow / prohibit the passage of gas in the gas pipe 11A, and may be configured by, for example, an on-off valve. The first gas meter 31A is configured to detect the flow rate of the gas flowing through the gas pipe 11A and output the detected gas flow rate to the monitoring center 200.

Further, a plurality of gas pipes 12A, 12B, 12C are connected to the gas pipe 11A. A second valve 22A and a second gas meter 32A are installed on the upstream side of the gas pipe 12A. The second valve 22A is configured to allow / prohibit the passage of gas in the gas pipe 12A, and may be configured by, for example, an on-off valve. The second gas meter 32A is configured to detect the flow rate of the gas flowing through the gas pipe 12A and output the detected gas flow rate to the monitoring center 200.

The gas pipes 12A are connected to gas flow paths 110A to 110E for supplying gas to the houses 100A to 100E belonging to the middle areas 70A (70B, 70N). Gas meters 120 (third gas meters 120A to 120E) are installed in the gas flow paths 110A to 110E, respectively.

In the first embodiment, five dwellings 100A to 100E are shown as the dwellings 100 belonging to the middle area 70A (70B, 70N), but this is for convenience of explanation, and the middle area 70A ( The number of dwellings 100 subordinate to 70B, 70N) may be tens, hundreds, thousands, or tens of thousands.

Further, when it is not necessary to distinguish each dwelling 100A to 100E, it may be referred to as dwelling 100. Similarly, when it is not necessary to distinguish between the gas flow paths 110A to 110E, it may be referred to as a gas flow path 110. Further, when it is not necessary to distinguish between the third gas meters 120A to 120E, it may be referred to as a gas meter 120.

Further, since the middle areas 70B and 70N are configured in the same manner as the middle areas 70A, detailed description thereof will be omitted.

The gas meter 120 acquires a gas flow rate, which is the flow rate of gas flowing through the gas flow path 110, detects the gas pressure in the gas flow path 110, and transmits the acquired gas flow rate and gas pressure to the monitoring center 200. It is configured to output.

Further, the monitoring center 200 was acquired by each gas meter 120 by comparing the flow rate of the gas flowing through the gas pipe 11A and / or the gas pipe 12A with the total gas flow rate acquired by each gas meter 120. Based on the first gas pressure, which is the gas pressure detected when there is no gas flow rate, the gas in the step (A) and the step (A) for determining gas leakage from the gas pipe 11A and / or the gas pipe 12A. Step to identify the place where the gas leak occurs based on the position information of each gas meter 120 and the first gas pressure detected by each gas meter 120 when it is determined that the leak has occurred. (B) and are configured to be executed.

Here, the configurations of the gas meter 120 and the monitoring center 200 will be specifically described with reference to FIGS. 1 to 3.

FIG. 3 is a schematic diagram showing a schematic configuration of a gas meter and a monitoring center of the gas leak detection system shown in FIG. 1.

As shown in FIG. 3, the gas meter 120 has a flow rate acquisition unit 1, a pressure detection unit 2, and a control unit 50. Further, the monitoring center 200 has a control unit 60.

The flow rate acquisition unit 1 may be composed of, for example, a known flow rate measurement unit. Further, the flow rate acquisition unit 1 may be composed of a flow rate measurement unit and a memory that stores the flow rate information detected by the flow rate measurement unit and calculated by the control unit 50, and transmits / receives to / from the monitoring center 200. Therefore, it may be configured by a road survey. As the flow rate measuring unit, for example, a flow rate measuring unit having a transmitter / receiver made of an ultrasonic vibrator and an oscillation circuit made of a crystal oscillator or the like may be used.

As the pressure detection unit 2, a known pressure detection unit that measures (detects) the pressure of the gas flowing through the gas flow path 110 can be adopted.

The control unit 50 may be configured by a microcomputer, an MPU, a PLC (Programmable Logic Controller), a logic circuit, or the like. Further, the control unit 50 has a calculation unit 51, a storage unit 52, and a wireless module 53.

A CPU or the like can be used as the calculation unit 51, and a known memory such as a ROM and / or a RAM can be used as the storage unit 52. The wireless module 53 is configured to transmit and receive to and from the wireless module 63 of the monitoring center 200.

The control unit 60 of the monitoring center 200 may be configured by a microcomputer, an MPU, a PLC (Programmable Logic Controller), a logic circuit, or the like. Further, the control unit 60 includes a calculation unit 61, a storage unit 62, a wireless module 63, and a notification unit 64.

A CPU or the like can be used as the calculation unit 61, and a known memory such as a ROM and / or a RAM can be used as the storage unit 62. The wireless module 63 is configured to transmit and receive to and from the wireless module 53 of the gas meter 120.

The notification unit 64 may have any configuration as long as it can notify the outside of the warning of the occurrence of gas leakage. As a mode of notifying the outside, for example, a mode of displaying character data, an image data, or the like on the screen of a monitor or the like installed in the monitoring center 200 may be used, and the mode may be notified by light or color by an alarm lamp or the like. It may be a mode of notifying by voice by a speaker, a siren or the like. Further, the mode may be such that a smartphone, a mobile phone, a tablet computer, or the like is notified by e-mail or an application via a communication network.

[Operation and effect of gas leak detection system]
Next, the operation and operation / effect of the gas leak detection system 300 according to the first embodiment will be described with reference to FIGS. 1 to 5. The following operations are executed by the arithmetic unit 61 of the control unit 60 in the monitoring center 200 reading the program stored in the storage unit 62.

FIG. 4 is a flowchart showing an example of the operation of the gas leak detection system according to the first embodiment.

First, as shown in FIGS. 1 and 2, gas leaks between the portion of the gas pipe 12A to which the gas flow path 110B is connected and the portion to which the gas flow path 110C is connected (gas leak point 600). Is occurring.

Further, when the pressure detection unit 2 of the gas meter 120 (for example, the third gas meter 120E) belonging to a certain area (for example, a large area 500A) measures the pressure of the gas flowing in the gas flow path 110, another case. Even if gas is used in the dwelling 100 belonging to the area (for example, the large area 500B), it is assumed that the pressure value measured by the third gas meter 120E is hardly affected.

That is, when gas is used in the residence 100 belonging to another area (for example, large area 500B), the pressure measured by the pressure detection unit 2 of the gas meter 120 belonging to one area (for example, large area 500A). The value and the pressure detection unit 2 of the gas meter 120 belonging to one area (for example, large area 500A) measured when gas was not used in the dwelling 100 belonging to another area (for example, large area 500B). The difference between the pressure value and the pressure value shall be small enough. Therefore, the presence or absence of gas in other areas does not affect the gas leak determination and the gas leak location identification, which will be described later.

Then, as shown in FIG. 4, the calculation unit 61 of the monitoring center 200 acquires the flow rate of the gas flowing through the gas pipe (step S101).

At this time, the calculation unit 61 of the monitoring center 200 may acquire the flow rate of the gas flowing through the entire monitoring area 400. That is, the calculation unit 61 of the monitoring center 200 may acquire the flow rate of the gas detected by the first gas meter 31A and the first gas meter 31B.

Further, the calculation unit 61 of the monitoring center 200 may separately acquire the flow rate of the gas flowing in the large area 500A and the flow rate of the gas flowing in the large area 500B. That is, the calculation unit 61 of the monitoring center 200 acquires the flow rate of the gas detected by the first gas meter 31A as the flow rate of the gas flowing in the large area 500A, and the flow rate of the gas detected by the first gas meter 31B. May be obtained as the flow rate of the gas flowing in the large area 500B.

Further, the calculation unit 61 of the monitoring center 200 may separately acquire the flow rate of the gas flowing in each of the middle areas 70A to 70N. That is, the calculation unit 61 of the monitoring center 200 acquires the flow rate of the gas detected by the second gas meter 32A as the flow rate of the gas flowing in the middle area 70A, and the flow rate of the gas detected by the second gas meter 32B is medium. It may be acquired as the flow rate of the gas flowing in the area 70B, and the flow rate of the gas detected by the second gas meter 32N may be acquired as the flow rate of the gas flowing in the middle area 70N.

Next, the calculation unit 61 of the monitoring center 200 acquires a gas flow rate, which is the flow rate of the gas detected (acquired) by the gas meter 120, from each gas meter 120 (step S102). At this time, the calculation unit 61 of the monitoring center 200 acquires the gas flow rate from each gas meter 120 belonging to the area corresponding to the gas flow rate acquired in step S101.

Specifically, for example, when the calculation unit 61 of the monitoring center 200 acquires the gas flow rate for each of the large area 500A and the large area 500B in step S101, the calculation unit 61 belongs to each of the large areas 500A and 500B. The gas flow rate is acquired from each gas meter 120.

Next, the calculation unit 61 of the monitoring center 200 calculates the total gas flow rate acquired in step S102 (step S103). Next, in the calculation unit 61 of the monitoring center 200, the value obtained by subtracting the total gas flow rate calculated in step S103 from the gas flow rate in the gas pipe acquired in step S101 is larger than a predetermined first threshold value set in advance. Whether or not it is determined (step S104).

At this time, the monitoring center 200 may determine whether or not there is a gas leak in the entire monitoring area 400. Further, the monitoring center 200 may execute the determination of the presence or absence of gas leakage in the large area 500A and the determination of the presence or absence of gas leakage in the large area 500B in parallel. Further, the monitoring center 200 may execute the determination of the presence or absence of gas leakage in parallel in each of the middle areas 70A to 70N.

Here, the first threshold value can be set in advance by an experiment or the like, and may be, for example, 3 L / h.

When the calculation unit 61 of the monitoring center 200 determines that the value obtained by subtracting the total gas flow rate calculated in step S103 from the gas flow rate in the gas pipe acquired in step S101 is equal to or less than the first threshold value (in step S104). In No), it can be determined that no gas leakage has occurred, and the process returns to step S101.

On the other hand, when the calculation unit 61 of the monitoring center 200 determines that the value obtained by subtracting the total gas flow rate calculated in step S103 from the gas flow rate in the gas pipe acquired in step S101 is larger than the first threshold value (step). In Yes) in S104, it is determined that gas leakage has occurred in the gas pipe (step S105). The calculation unit 61 of the monitoring center 200 may notify the outside by the notification unit 64 that gas leakage has occurred in the gas pipe when the process of step S105 is executed.

Next, the calculation unit 61 of the monitoring center 200 acquires the first gas pressure, which is the gas pressure detected by the pressure detection unit 2 when the flow rate acquisition unit 1 of each gas meter 120 detects that there is no gas flow rate. (Step S106).

At this time, the calculation unit 61 of the monitoring center 200 determines that a gas leak has occurred, and the first gas pressure detected by each gas meter 120 installed in the large area (here, the large area 500A). May be obtained.

Further, the calculation unit 61 of the monitoring center 200 may acquire the first gas pressure detected by each gas meter 120 installed in the monitoring area 400.

Here, "the flow rate acquisition unit 1 of each gas meter 120 has no gas flow rate" means a state in which gas is not used in each dwelling 100, and a state in which gas does not flow in the gas flow path 110. Is. Therefore, the calculation unit 61 of the monitoring center 200 can acquire a pressure value that is not affected by the pressure fluctuation due to the flow of gas in the gas flow path 110.

When the gas flow rate and the gas pressure are stored in the storage unit 62, the calculation unit 61 of the monitoring center 200 may acquire the first gas pressure from the storage unit 62, and the storage of each gas meter 120. The first gas pressure may be acquired from the gas flow rate and the gas pressure stored in the unit 52.

Next, the calculation unit 61 of the monitoring center 200 creates mapping data based on the position information of each gas meter 120 stored in the storage unit 62 and the first gas pressure acquired in step S106 (). Step S107), the gas leak location is specified (step S108).

At this time, the calculation unit 61 of the monitoring center 200 displays, for example, the position information of each gas meter 120 and the first gas pressure acquired in step S106 on known map information, as shown in FIG. May be good. Further, in the calculation unit 61 of the monitoring center 200, when the first gas pressure detected by a certain gas meter 120 is equal to or less than a preset gas pressure value, the vicinity of the place where the gas meter 120 is installed is determined. It may be specified as a gas leak location.

Here, the preset gas pressure value may be 50 to 70 kPa when the pressure of the gas flowing through the gas pipe is low pressure (less than 0.1 MPa). Further, as the gas pressure value, when the pressure of the gas flowing through the gas pipe is medium pressure A (0.1 MPa to less than 0.3 MPa), it may be less than 0.1 MPa, and medium pressure B (0). When it is (3 MPa to less than 1.0 MPa), it may be less than 0.3 MPa. Further, the gas pressure value may be less than 1.0 MPa when the pressure of the gas flowing through the gas pipe is high pressure (1.0 MPa or more).

Further, the calculation unit 61 of the monitoring center 200 divides the monitoring area 400 into a plurality of large areas (here, large area 500A and large area 500B), and determines in which large area the gas leak occurs. (Identify which large area is the gas leak location).

Specifically, the calculation unit 61 of the monitoring center 200 has, for example, the average value of the first gas pressure detected by each gas meter 120 belonging to the large area 500A and the first gas meter 120 detected by each gas meter 120 belonging to the large area 500B. 1 The gas leak location may be specified by calculating the average value of the gas pressure and comparing the calculated average value.

For example, as shown in FIGS. 1 and 2, when gas leakage occurs at the gas leakage point 600, the average value of the first gas pressure in the large area 500A is the first gas pressure in the large area 500B. It becomes smaller than the average value of. Therefore, the calculation unit 61 of the monitoring center 200 can determine that a gas leak has occurred in the large area 500A.

Next, the calculation unit 61 of the monitoring center 200 determines the average value of the first gas pressure detected by each gas meter 120 belonging to the large area 500B and the first gas pressure detected by each gas meter 120 belonging to the large area 500A. The difference between the two may be calculated, and the calculated value and the position information of each gas meter 120 may be displayed on known map information.

As shown in FIG. 2, in the third gas meter 120D and the third gas meter 120E arranged on the upstream side of the gas leak point 600, the difference in the first gas pressure is small, and the gas meter 120E is installed on the downstream side of the gas leak point 600. It is presumed that the difference in the first gas pressure becomes large in the third gas meters 120A, 120B, and 120C.

As a result, the calculation unit 61 of the monitoring center 200 can identify the gas leak location in the gas pipe.

The calculation unit 61 of the monitoring center 200 determines whether or not a gas leak has occurred in each of the medium areas after determining that a gas leak has occurred in the large area 500A, and the gas leak has occurred. In the middle area determined to be, the place where the gas leak occurs may be specified.

Specifically, the calculation unit 61 of the monitoring center 200 executes the processes of steps S101 to S104 for each medium area after determining that gas leakage has occurred in the large area 500A (step S105). To determine if there is a gas leak.

Next, the arithmetic unit 61 of the monitoring center 200 executes the processes of steps S107 to S109 in the middle area where it is determined that the gas leak has occurred, and identifies the place where the gas leak has occurred. You may.

At this time, when the first gas pressure detected by a certain gas meter 120 is equal to or less than a preset gas pressure value, the calculation unit 61 of the monitoring center 200 has a middle area where the gas meter 120 is installed. , May be specified as a gas leak location.

Further, the calculation unit 61 of the monitoring center 200 determines that a gas leak has occurred in the large area 500A, and then has the average value of the first gas pressure detected by each gas meter 120 belonging to the medium area 70A and the medium. The first calculated by calculating the average value of the first gas pressure detected by each gas meter 120 belonging to the area 70B and the average value of the first gas pressure detected by each gas meter 120 belonging to the middle area 70N. By comparing the average values of the gas pressures, it may be possible to identify in which middle area the gas leak occurs.

In this way, the area may be subdivided, and the calculation unit 61 of the monitoring center 200 may specify the gas leak location in the gas pipe.

Next, the calculation unit 61 of the monitoring center 200 notifies the gas leak location specified in step S108 to the outside by the notification unit 64 (step S109), and ends this program.

Next, another example of the operation of the gas leak detection system according to the first embodiment will be described with reference to FIG.

FIG. 5 is a flowchart showing another example of the operation of the gas leak detection system according to the first embodiment.

As shown in FIG. 5, the calculation unit 61 of the monitoring center 200 acquires a gas flow rate, which is the flow rate of the gas detected (acquired) by the gas meter 120, from each gas meter 120 belonging to the monitoring area 400 (step S201). ).

Next, the calculation unit 61 of the monitoring center 200 acquires the first gas pressure, which is the gas pressure detected by the pressure detection unit 2 when the flow rate acquisition unit 1 of each gas meter 120 detects that there is no gas flow rate. (Step S202).

Next, the calculation unit 61 of the monitoring center 200 determines whether or not the first gas pressure acquired in step S202 is larger than the preset gas pressure value (step S203).

Here, the preset gas pressure value may be 50 to 70 kPa when the pressure of the gas flowing through the gas pipe is low pressure (less than 0.1 MPa). Further, as the gas pressure value, when the pressure of the gas flowing through the gas pipe is medium pressure A (0.1 MPa to less than 0.3 MPa), it may be less than 0.1 MPa, and medium pressure B (0). When it is (3 MPa to less than 1.0 MPa), it may be less than 0.3 MPa. Further, the gas pressure value may be less than 1.0 MPa when the pressure of the gas flowing through the gas pipe is high pressure (1.0 MPa or more).

When the first gas pressure acquired in step S202 is equal to or less than the preset gas pressure value (No in step S203), the calculation unit 61 of the monitoring center 200 determines that no gas leakage has occurred. It can be determined, and the process returns to step S201.

On the other hand, when the calculation unit 61 of the monitoring center 200 determines that the first gas pressure acquired in step S202 is larger than the preset gas pressure value (Yes in step S203), the gas is connected to the gas pipe. It is determined that the leakage has occurred (step S204). The calculation unit 61 of the monitoring center 200 may notify the outside by the notification unit 64 that gas leakage has occurred in the gas pipe when the process of step S204 is executed.

Next, the calculation unit 61 of the monitoring center 200 creates mapping data based on the position information of each gas meter 120 stored in the storage unit 62 and the first gas pressure acquired in step S202 (). Step S205), the gas leak location is specified (step S206). The gas leak location may be specified by the method described above.

Next, the calculation unit 61 of the monitoring center 200 notifies the gas leak location specified in step S206 to the outside by the notification unit 64 (step S207), and ends this program.

In the gas leak detection system 300 according to the first embodiment configured in this way, it is possible to identify the gas leak location in the gas pipe. Further, since the gas leak location can be specified, the maintenance work can be easily executed.

In the invention disclosed in Patent Document 1, although it is possible to detect that a gas leak has occurred, the leaked portion cannot be specified. Therefore, the maintenance worker needs to inspect the entire area of the shared pipe, and the maintenance work takes time.

On the other hand, in the gas leak detection system 300 according to the first embodiment, the location of the leak can be easily identified as compared with the invention disclosed in Patent Document 1, and the time required for maintenance work can be shortened. ..

Needless to say, the gas leak detection system 300 according to the first embodiment can specify the gas leak location even for the shared pipe in the apartment house.

From the above description, many improvements or other embodiments of the present invention will be apparent to those skilled in the art. Therefore, the above description should be construed as an example only and is provided for the purpose of teaching those skilled in the art the best mode of carrying out the invention. The details of its structure and / or function can be substantially changed without departing from the present invention. In addition, various inventions can be formed by an appropriate combination of the plurality of components disclosed in the above-described embodiment.

The gas leak detection system according to the present invention is useful because it can identify the gas leak location.

1 Flow acquisition unit 2 Pressure detection unit 11A Gas pipe 11B Gas pipe 12A Gas pipe 12N Gas pipe 12B Gas pipe 21A 1st valve 21B 1st valve 22A 2nd valve 22B 2nd valve 22N 2nd valve 31A 1st gas meter 31B 1st Gas meter 32A 2nd gas meter 32B 2nd gas meter 32N 2nd gas meter 50 Control unit 51 Calculation unit 52 Storage unit 53 Wireless module 60 Control unit 61 Calculation unit 62 Storage unit 63 Wireless module 64 Notification unit 70A Medium area 70B Medium area 70N Medium area 100 Dwelling 100A Dwelling 100B Dwelling 100C Dwelling 100D Dwelling 100E Dwelling 110 Gas flow path 110A Gas flow path 110B Gas flow path 110C Gas flow path 110D Gas flow path 110E Gas flow path 120 Gas meter 120A 3rd gas meter 120B 3rd gas meter 120C 3rd gas meter 120D 3rd gas meter 120E 3rd gas meter 200 Monitoring center 300 Gas leak detection system 400 Monitoring area 500A Large area 500B Large area 600 Gas leak location

Claims (6)

Gas pipes that supply gas to each house,
A gas meter installed in each of the houses to acquire the gas flow rate in the gas flow path connected to the gas pipe and to detect the gas pressure in the gas flow path.
It is equipped with a monitoring center that collects the gas flow rate and the gas pressure from each of the gas meters.
The monitoring center compares the flow rate of the gas flowing through the gas pipe with the sum of the gas flow rates acquired by each of the gas meters and / or has no flow rate of the gas acquired by each of the gas meters. The step (A) of determining the presence or absence of leakage of the gas from the gas pipe based on the first gas pressure, which is the gas pressure sometimes detected.
When it is determined in the step (A) that a gas leak has occurred, the gas leak occurs based on the position information of each gas meter and the first gas pressure detected by each gas meter. A gas leak detection system configured to perform the step (B) of identifying the location of the occurrence. In the monitoring center, when the first gas pressure detected by the gas meter in the step (B) is equal to or less than a preset predetermined gas pressure value, the vicinity of the location where the gas meter is installed is located. The gas leak detection system according to claim 1, which identifies the place where the gas leak is occurring. The monitoring center divides each of the dwellings into a plurality of large areas for each of the plurality of dwellings.
In the step (A), the presence or absence of gas leakage is determined for each of the large areas.
In the step (B), it is configured to specify the place where the gas leak occurs in the large area where it is determined that the gas leak has occurred in the step (A). The gas leak detection system according to claim 1 or 2. The monitoring center divides the large area identified as the place where the gas leak occurs into a plurality of medium areas for each of a plurality of residences.
In the step (B), the presence or absence of the gas leak is determined for each of the middle areas (B1), and in the middle area where it is determined that the gas leak has occurred in the step (B1). The gas leak detection system according to claim 3, wherein the gas leak detection system is configured to identify the location where the gas leak is occurring (B2). The monitoring center divides each of the dwellings into a plurality of large areas for each of the plurality of dwellings.
In the step (B), the average value of the first gas pressure detected by the gas meter in each of the large areas is calculated, and the calculated average value of the first gas pressure is small in the large area as compared with the other large areas. The gas leak detection system according to claim 1 or 2, wherein the step (B3) for identifying the location where the gas leak is occurring is performed. The monitoring center divides the large area identified as the place where the gas leak occurs into a plurality of medium areas for each of a plurality of residences.
In the step (B), the average value of the first gas pressure detected by the gas meter in each of the middle areas is calculated, and the calculated average value of the first gas pressure is smaller in the middle area than in the other middle areas. The gas leak detection system according to claim 5, which is configured to perform a step (B4) of identifying a location where a gas leak is occurring.

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