JP6295955B2 - Leakage position specifying device, leak position specifying method, leak position specifying program, and leak position specifying system - Google Patents

Description

  The present invention relates to a leak position specifying device, a leak position specifying method, a leak position specifying program, and a leak position specifying system.

  As social infrastructure, facilities such as water and sewage networks, high-pressure chemical pipelines such as gas and oil, high-speed railways, long-span bridges, skyscrapers, large passenger planes, and automobiles are built. One of the important members in these facilities is piping for passing fluids such as gas and water. Piping may fail due to deterioration or natural disasters. When a pipe breaks down and fluid leaks out, it is necessary to repair the failed part. Therefore, it is necessary to detect the leakage of the fluid in the piping and specify the fluid leakage position in the piping. Hereinafter, inspections performed on fluid leakage in pipes are collectively referred to as leakage inspection.

  A general leak test is an auditory sensory test in which a leaked sound is heard manually. However, since pipes are often installed in the ground or at high places, manual inspection involves danger and great labor. Therefore, an apparatus for performing a leakage inspection has been proposed.

  The leak detection apparatus described in Patent Document 1 detects a leak by converting sound detected around a pipe into an electric signal and analyzing the electric signal. This apparatus decomposes each electric signal obtained from the acquired sound into different frequencies using a plurality of bandpass filters. And the magnitude | size of the amplitude of the electric signal of each frequency is compared with a threshold value. And in all the said some signals, when the magnitude | size of the amplitude of an electrical signal exceeds a threshold value, it determines with it being a leak.

  The device described in Patent Document 2 determines the presence or absence of water leakage from the ratio between the number of counts when the vibration level of the pipe due to water leakage exceeds the determination level and the number of counts less than the determination level.

  The device described in Patent Document 3 detects the presence or absence of water leakage using detection signals acquired by underwater microphones installed at both ends of the inspection section. In this method, the presence or absence of water leakage is determined by adding a waveform having a high correlation function of a signal detected based on the set temporary sound source position to create a composite waveform.

  The device described in Patent Document 4 uses a synchronization signal as a measurement start reference and acquires vibrations at a plurality of locations for a predetermined time to determine the presence or absence of water leakage.

JP-A-62-0555540 JP 2012-37492 A JP-A-11-72409 JP 2006-317172 A

  A lot of labor is required for maintenance of an apparatus used for specifying a leakage position in piping. One reason is that pipes are often installed in the ground or at high places, and therefore, devices used for specifying the leakage position are often installed in the ground or at high places. Another reason is that a large number of devices used for specifying the leak position are installed in the piping. In order to reduce the frequency of maintenance of the apparatus used for specifying the leak position, the present inventor reduces the energy consumption of the apparatus used for specifying the leak position and extends the operating life of the apparatus used for specifying the leak position. Considered to do.

  An object of the present invention is to provide a leak position specifying device that reduces energy consumed by a device used for specifying a leak position in piping, a leak position specifying method and a leak position specifying program for controlling the leak position specifying device, and a leak position It is an object of the present invention to provide a leakage position specifying system that consumes less energy by a device that is specifically used.

The leak position specifying device provided by the present invention specifies the leak position of fluid in the pipe using a plurality of vibration measuring devices installed in the pipe. The vibration measurement device includes a measurement execution unit that measures vibration at a different time from another adjacent vibration measurement device. And the said leak position specific | specification apparatus specifies the said vibration measurement apparatus from which the said measurement execution means measured the vibration which shows the leak of the said piping among said several vibration measurement apparatuses as a 1st measurement apparatus. Among the two vibration measurement devices adjacent to the first measurement device and the first measurement device, the vibration measurement device having a greater degree of leakage indicated by the vibration measured by the measurement execution unit is identified as the second measurement device. There is a second measuring device specifying unit, and a position specifying unit that specifies that the position between the installation position of the first measuring device and the installation position of the second measuring device is a leakage position in the pipe.

  The leakage position specifying program provided by the present invention is a program for causing a computer to have the function of each functional component of the leakage position specifying apparatus provided by the present invention.

A leak position specifying system provided by the present invention includes a plurality of vibration measuring devices installed in a pipe, and a leak position specifying device for specifying a fluid leak position in the pipe using the plurality of vibration measuring devices. A location system. The vibration measurement device includes a measurement execution unit that measures vibration at a different time from another adjacent vibration measurement device. And the said leakage position specific | specification apparatus specifies the said vibration measuring device from which the said measurement execution means measured the vibration which shows the leakage of the said piping among said several vibration measuring devices as a 1st measuring device. Among the two vibration measurement devices adjacent to the first measurement device and the first measurement device, the vibration measurement device having a greater degree of leakage indicated by the vibration measured by the measurement execution unit is identified as the second measurement device. There is a second measuring device specifying unit, and a position specifying unit that specifies that the position between the installation position of the first measuring device and the installation position of the second measuring device is a leakage position in the pipe.

The leak position specifying method provided by the present invention is a leak position specifying method for specifying a leak position of fluid in the pipe using a plurality of vibration measuring devices installed in the pipe, which is executed by a computer. The vibration measurement device includes a measurement execution unit that performs measurement at a time different from that of another adjacent vibration measurement device. And the said leak position specific method is a 1st measuring device which specifies the said vibration measuring device from which the said measurement execution means measured the vibration which shows the leakage of the said piping among said several vibration measuring devices as a 1st measuring device. Of the two vibration measurement devices adjacent to the first measurement device and the specifying step, the vibration measurement device having a greater degree of leakage indicated by the vibration measured by the measurement execution unit is specified as the second measurement device. A second measurement device specifying step, and a position specifying step for specifying that the position between the installation position of the first measurement device and the installation position of the second measurement device is a leakage position in the pipe.

  ADVANTAGE OF THE INVENTION According to this invention, the energy consumed by the apparatus utilized for specification of a leak position can be decreased.

  The above-described object and other objects, features, and advantages will become more apparent from the preferred embodiments described below and the accompanying drawings.

It is a block diagram which shows the leak position specific device which concerns on Embodiment 1 with the use environment. It is a figure which illustrates notionally the operation | movement of the leak position specific apparatus which concerns on Embodiment 1. FIG. It is a block diagram which shows the leak position specific device which concerns on Embodiment 1 which acquires information from an external device with the use environment. 6 is a flowchart illustrating an example of a flow of a leak position specifying process performed by the leak position specifying apparatus according to the first embodiment. It is a block diagram which shows the leak position specific device which concerns on Embodiment 2 with the use environment. 10 is a flowchart illustrating an example of a flow of a leakage inspection process performed by the leakage position specifying device according to the second embodiment. It is a block diagram which shows the leak position specific system which concerns on Embodiment 3. It is a figure which shows an example of grouping of the vibration measuring device in the leak position specific | specification system which concerns on Embodiment 3. FIG. 12 is a graph illustrating an example of a point in time when each vibration measuring device of the leakage position specifying system according to the third embodiment operates. 12 is a graph illustrating another example of a point in time when each vibration measuring device 3000 of the leakage position specifying system according to the third embodiment operates.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. In all the drawings, the same reference numerals are given to the same components, and the description will be omitted as appropriate.

  In the following description, each component of each device is not a hardware unit configuration but a functional unit block. Each component of each device includes a CPU, memory, a program that realizes the components shown in the figure loaded in the memory, a storage medium such as a hard disk for storing the program, and a network connection interface. It is realized by any combination of software and software. There are various modifications of the implementation method and apparatus.

[Embodiment 1]
<Overview>
FIG. 1 is a diagram showing a leakage position specifying device 2000 according to the present embodiment, together with its use environment. In FIG. 1, arrows indicate the flow of information.

  Leakage position specifying device 2000 uses a plurality of vibration measuring devices 3000 installed in a pipe to specify a position where fluid is leaking in the pipe (hereinafter referred to as a leak position).

  The vibration measurement device 3000 includes a measurement execution unit 3020 that measures vibration. The measurement execution unit 3020 operates at a different time from the measurement execution unit 3020 of another vibration measurement device 3000 adjacent to the vibration measurement device 3000.

  The leakage position specifying device 2000 includes a first measuring device specifying unit 2010, a second measuring device specifying unit 2020, and a position specifying unit 2030. The first measurement device specifying unit 2010 specifies the vibration measurement device 3000 from which the measurement execution unit 3020 has measured vibrations that satisfy a predetermined condition among the plurality of vibration measurement devices 3000. Hereinafter, the specified vibration measuring device 3000 is referred to as a first measuring device.

  The second measuring device specifying unit 2020 specifies one of the vibration measuring devices 3000 adjacent to the first measuring device 3000. Hereinafter, the specified vibration measuring device 3000 is referred to as a second measuring device.

  The position specifying unit 2030 specifies the leak position based on the installation positions of the first measurement device and the second measurement device. For example, the position specifying unit 2030 specifies that the position between the installation position of the first measurement device and the installation position of the second measurement device is a leakage position.

  FIG. 2 is a diagram conceptually illustrating a method in which the leakage position specifying device 2000 specifies a leakage position using a plurality of vibration measuring devices 3000. In FIG. 2, the leak position specifying device 2000 specifies the leak position using six vibration measuring devices 3000-1 to 6 having IDs 1 to 6, respectively. The vibration measuring devices 3000-1 to 3000-6 are installed along the extending direction of the pipe 10.

  In FIG. 2, it is assumed that the vibration measured by the vibration measuring device 3000-4 indicates leakage. In this case, as shown in FIG. 2A, the leakage position specifying device 2000 uses the first measuring device specifying unit 2010 to specify the vibration measuring device 3000-4 as the first measuring device.

  In the above case, the second measurement device specifying unit 2020 compares the degree of leakage indicated by the vibrations measured by the vibration measurement device 3000-3 and the vibration measurement device 3000-5 adjacent to the vibration measurement device 3000-4. To do. And the 2nd measurement apparatus specific | specification part 2020 specifies the vibration measurement apparatus 3000 with the larger degree of the leakage which the measured vibration shows among these two vibration measurement apparatuses 3000 as a 2nd measurement apparatus. In the case of this example, it is assumed that the vibration measurement device 3000-3 has a greater degree of leakage indicated by the measured vibration. In this case, as illustrated in FIG. 2B, the second measurement device specifying unit 2020 specifies the vibration measurement device 3000-3 as the second measurement device.

  Finally, the position specifying unit 2030 specifies that the gap between the installation position of the first measurement device and the installation position of the second measurement device is a leakage position in the pipe 10. The installation position of the vibration measuring device 3000 is represented by the X coordinate of the place where the vibration measuring device 3000 is located, for example, when the extending direction of the pipe 10 is the X-axis direction. For example, in the case of this example, as FIG.2 (b) shows, the X coordinate of vibration measuring device 3000-1-6 is represented by X1-X6, respectively. Therefore, the installation position of the vibration measurement device 3000-4 that is the first measurement device is X4, and the installation position of the vibration measurement device 3000-3 that is the second measurement device is X3. Therefore, the position specifying unit 2030 specifies that the hatched portion between X4 and X3 in the pipe 10 is the leakage position.

  With the above operation, the leak position specifying device 2000 specifies the leak position using a plurality of vibration measurement devices 3000 that operate at different times from the adjacent vibration measurement device 3000. Therefore, the leakage position specifying device 2000 consumes less energy than the vibration measuring device 3000 used for specifying the leakage position, as compared with the case where all the vibration measuring devices 3000 are operated simultaneously to specify the leakage position. Furthermore, the leakage position specifying device 2000 consumes less peak power than the vibration measuring device 3000 used for specifying the leakage position as compared with the case where all the vibration measuring devices 3000 are operated simultaneously to specify the leakage position.

  Details of this embodiment will be described below.

<Details of vibration measuring device 3000>
For example, the vibration measuring device 3000 is installed along the extending direction of the same pipe. The vibration measuring device 3000 installed in the pipe may be installed in contact with the pipe or may be set apart from the pipe. When installed away from the piping, for example, the vibration measuring device 3000 is installed in the ground around the piping, the ground, or the like.

  For example, the vibration measuring device 3000 measures vibration of a pipe or vibration propagated from the pipe. For example, the vibration measuring device 3000 includes a vibration sensor that measures vibration of a pipe or vibration propagated from the pipe. As the vibration sensor, for example, a piezoelectric vibration sensor having a piezoelectric element can be suitably used. In addition, each vibration measurement device 3000 may use the same type of vibration sensor, or may use different types of vibration sensors.

<Details of First Measuring Device Identification Unit 2010>
The first measuring device specifying unit 2010 specifies, as the first measuring device, the vibration measuring device 3000 from which the measurement execution unit 3020 has measured vibration satisfying a predetermined condition among the plurality of vibration measuring devices 3000. For example, the predetermined condition is that the vibration indicates leakage of the pipe. The first measuring device specifying unit 2010 determines whether or not the vibration measured by the vibration measuring device 3000 indicates leakage by various methods. For example, the first measurement device specifying unit 2010 acquires information indicating whether or not the vibration measured by each vibration measurement device 3000 indicates leakage from each vibration measurement device 3000. In this case, the measurement execution unit 3020 of the vibration measurement device 3000 has a function of determining whether or not the vibration to be inspected indicates leakage. The first measuring device specifying unit 2010 sets the vibration measuring device 3000 whose determination result is leakage as the first measuring device. In addition, the first measurement device specifying unit 2010 may acquire the determination result only from the vibration measurement device 3000 in which the determination result by the measurement execution unit 3020 indicates that there is leakage. In this case, the 1st measuring device specific | specification part 2010 makes the vibration measuring device 3000 which acquired the said determination result a 1st measuring device. In this case, the leakage position specifying device 2000 and the vibration measuring device 3000 are connected to be communicable. The connection method between the leakage position specifying device 2000 and the vibration measuring device 3000 may be wired connection, wireless connection, or a connection method in which wired connection and wireless connection are mixed.

  In addition, for example, the leakage position specifying device 2000 has a leakage determination unit that acquires information indicating vibration measured by the vibration measuring device 3000 and determines whether the vibration indicated by the acquired information indicates leakage. Also good. In this case, the 1st measuring device specific | specification part 2010 acquires the information which specifies the vibration measuring device 3000 from which the measured vibration shows a leakage from this leak determination part.

  In addition, for example, as illustrated in FIG. 3, the first measurement device specifying unit 2010 causes the measured vibration to leak from the external device 4000 that determines whether the vibration measured by the vibration measurement device 3000 indicates leakage. Information for specifying the vibration measurement device 3000 shown, that is, information for specifying the first measurement device may be acquired. The external device 4000 is a server that is communicably connected to each vibration measuring device 3000, for example. In this case, each of the leakage position specifying device 2000 and each vibration measuring device 3000 is connected to be able to communicate with the external device 4000. The connection method between the leakage position specifying device 2000 and the external device 4000, and the vibration measuring device 3000 and the external device 4000 are both wired connection and wireless connection. A connection method may be used.

<Details of Second Measuring Device Identification Unit 2020>
For example, the second measurement device specifying unit 2020 specifies, as the second measurement device, the vibration measurement device 3000 having a greater degree of leakage indicated by the measured vibration among the two vibration measurement devices 3000 adjacent to the first measurement device. .

  The second measuring device specifying unit 2020 needs to determine which vibration measuring device 3000 is adjacent to the first measuring device. There are various methods for the second measuring device specifying unit 2020 to grasp the two vibration measuring devices 3000 adjacent to the first measuring device. For example, an ID may be given to each vibration measuring device 3000 so that the second measuring device specifying unit 2020 can specify the arrangement of the vibration measuring device 3000 based on the ID of the vibration measuring device 3000. In this case, the second measuring device specifying unit 2020 grasps the vibration measuring device 3000 adjacent to the first measuring device based on the ID of the first measuring device.

  For example, it is assumed that the ID for identifying the vibration measuring device 3000 is a number, and the vibration measuring device 3000 is arranged in the order of the number indicated by the ID. In this case, first, the position specifying unit 2030 acquires the ID of the first measuring device from the first measuring device specifying unit 2010. Here, a method by which the first measuring device specifying unit 2010 specifies the ID of the first measuring device will be described later. Then, the second measurement device specifying unit 2020 uses two vibration measurement devices 3000 whose ID is 1 smaller than the ID of the first measurement device and vibration measurement device 3000 whose ID is 1 larger than the ID of the first measurement device. The vibration measuring device 3000 adjacent to the measuring device is determined. For example, in the case of FIG. 2, each vibration measurement device 3000 is assigned IDs 1 to 6. In the case of FIG. 2, the first measurement device specifying unit 2010 specifies the vibration measurement device 3000-4 having an ID of 4 as the first measurement device. Therefore, the second measurement device specifying unit 2020 includes the vibration measurement device 3000-3 having ID 3 and the vibration measurement device 3000-5 having ID 5 being adjacent to the first measurement device. To find out.

  In addition, for example, the second measurement device specifying unit 2020 uses the installation position information indicating the combination of “ID of the vibration measurement device 3000 and the installation position of the vibration measurement device 3000” to set the installation position of each vibration measurement device 3000. May be determined. In this case, first, the second measuring device specifying unit 2020 acquires the ID of the first measuring device from the first measuring device specifying unit 2010. And the 2nd measuring device specific | specification part 2020 reads installation position information by using ID of a 1st measuring device as a key, and calculates the installation position of a 1st measuring device. Subsequently, the second measurement device specifying unit 2020 reads the installation position information using each of the two installation positions adjacent to the installation position of the first measurement device as a key. As a result, the second measurement device specifying unit 2020 determines the vibration measurement device 3000 installed at each of the two installation positions adjacent to the installation position of the first measurement device. The installation position information may be included in the leak position specifying device 2000, or may be included in an external device that is communicably connected to the leak position specifying device 2000. This external device may be the same as the external device 4000 shown in FIG. 3 or may be an external device different from the external device 4000.

  There are various methods by which the first measuring device specifying unit 2010 specifies the ID of the first measuring device. For example, when the first measurement device specifying unit 2010 acquires information from each vibration measurement device 3000, the ID of each vibration measurement device 3000 is acquired together with the information. For example, when the first measurement device specifying unit 2010 acquires information for specifying the first measurement device from the external device 4000, the first measurement device specifying unit 2010 uses the external device 4000 as information for specifying the first measurement device. To obtain the ID of the first measuring device.

<Leakage location identification process>
FIG. 4 is a flowchart showing an example of a flow of processing (hereinafter referred to as leakage position specifying processing) in which the leakage position specifying device 2000 of the present embodiment specifies a leakage position.

  In step S102, the first measuring device specifying unit 2010 determines whether or not the vibration measured by any of the vibration measuring devices 3000 indicates leakage. When the vibration measured by any of the vibration measurement devices 3000 indicates leakage, the leakage position specifying process proceeds to step S104. If none of the vibrations measured by each vibration measuring device 3000 indicates leakage, the leakage position specifying process returns to step S102 again.

  In step S104, the first measurement device specifying unit 2010 specifies the vibration measurement device 3000 whose measured vibration indicates leakage as the first measurement device.

  In step S106, the second measurement device specifying unit 2020 selects the vibration measurement device 3000 having a greater degree of leakage indicated by the measured vibration, from the two vibration measurement devices 3000 adjacent to the first measurement device. As specified.

  In step S108, the position specifying unit 2030 specifies that the gap between the installation position of the first measurement device and the installation position of the second measurement device is a leakage position in the pipe.

<Action and effect>
With the above configuration, according to the present embodiment, the leakage position specifying device 2000 specifies the leakage position in the pipe using the plurality of vibration measuring devices 3000 that operate at different times from the adjacent vibration measuring device 3000. . Specifically, the leakage position specifying device 2000 specifies the vibration measuring device 3000 as the first measuring device when the vibration measured by any one of the vibration measuring devices 3000 satisfies a predetermined condition. Furthermore, one of the two vibration measurement devices 3000 adjacent to the first measurement device is specified as the second measurement device. Then, the leakage position specifying device 2000 specifies that the leakage position in the pipe is between the installation position of the first measurement device and the installation position of the second measurement device.

  The vibration measuring device 3000 operates at a time different from the other adjacent vibration measuring devices 3000. Therefore, the leakage position specifying device 2000 can reduce the energy consumed by the vibration measuring device 3000 used for specifying the leakage position, as compared to the case where all the vibration measuring devices 3000 are operated simultaneously to specify the leakage position. Furthermore, the leak position specifying device 2000 can reduce the peak power consumed by the vibration measuring device 3000 used for specifying the leak position as compared to the case where the leak position is specified by operating all the vibration measurement devices 3000 simultaneously. it can.

[Embodiment 2]
<Overview>
FIG. 5 is a diagram showing the leakage position specifying device 2000 according to the present embodiment, together with its use environment. Among the functional blocks in FIG. 5, those having functional blocks with the same reference numerals in FIG. 1 have the same functions as the functional blocks in FIG. 1, and description thereof will be omitted as appropriate.

  The vibration measuring device 3000 further includes an operation stopping unit 3040 that receives an instruction from the leakage position specifying device 2000 and stops the operation of the vibration measuring device 3000.

  Leakage position identification device 2000 further includes a stop instruction unit 2040. When the first measuring device specifying unit 2010 specifies the first measuring device, the stop instruction unit 2040 is adjacent to the first measuring device before the second measuring device specifying unit 2020 specifies the second measuring device. An operation stop instruction is transmitted to the operation stop unit 3040 of the non-vibration measuring apparatus 3000.

  For example, when the first measuring device specifying unit 2010 specifies the first measuring device, the first measuring device is instructed to the stop instruction unit 2040 before the second measuring device specifying unit 2020 specifies the second measuring device. Send information that identifies The stop instruction unit 2040 instructs the vibration measurement device vibration measurement device 3000 not adjacent to the first measurement device to stop operation based on the information specifying the first measurement device acquired from the first measurement device specifying unit 2010. Send.

  There are various methods by which the stop instruction unit 2040 determines the vibration measurement device 3000 that is not adjacent to the first measurement device. For example, the stop instruction unit 2040 acquires information indicating the vibration measurement device 3000 adjacent to the first measurement device from the second measurement device specifying unit 2020. In this way, the stop instruction unit 2040 determines that the vibration measurement device 3000 other than the vibration measurement device 3000 adjacent to the first measurement device is the vibration measurement device 3000 that is not adjacent to the first measurement device.

  In addition, for example, the stop instruction unit 2040 may have a function of grasping the arrangement of the vibration measuring devices 3000 by the same method as the second measuring device specifying unit 2020 described in the first embodiment.

  The leakage position specifying device 2000 and the vibration measuring device 3000 are connected to be communicable. The connection method between the leakage position specifying device 2000 and the vibration measuring device 3000 may be wired connection, wireless connection, or a connection method in which wired connection and wireless connection are mixed.

  The operation of the leakage position specifying device 2000 in this embodiment will be described using the use environment shown in FIG. 2 in the first embodiment as an example. Similarly to the first embodiment, it is assumed that the leakage position specifying device 2000 specifies the vibration measuring device 3000-4 as the first measuring device. In this case, before the second measurement device specifying unit 2020 specifies the second measurement device, the stop instruction unit 2040 is not adjacent to the vibration measurement device 3000-4 that is the first measurement device. An operation stop instruction is transmitted to 1, 2, and 6.

<Operation flow>
FIG. 6 is a flowchart showing an example of the flow of the leak position specifying process performed by the leak position specifying apparatus 2000 of the present embodiment. The flowchart shown in FIG. 6 is the same as the flowchart shown in FIG. 4 except that step S202 is included between step S104 and step S106. Therefore, descriptions other than step S202 are omitted.

  In step S202, the stop instruction unit 2040 transmits an operation stop instruction to the vibration measurement device 3000 that is not adjacent to the first measurement device. Specifically, the stop instruction unit 2040 first acquires information for specifying the first measurement device from the first measurement device specification unit 2010. Then, the stop instruction unit 2040 transmits an operation stop instruction to the vibration measurement device 3000 that is not adjacent to the first measurement device. The operation stop unit 3040 that has received the operation stop instruction stops the operation of the vibration measuring device 3000 having the operation stop unit 3040.

<Action and effect>
With the above configuration, according to the present embodiment, when the leakage position specifying device 2000 specifies the first measurement device, the vibration measurement is not adjacent to the first measurement device before specifying the second measurement device. The operation of the device 3000 is stopped. By doing so, the leakage position specifying device 2000 reduces the number of vibration measuring devices 3000 used when specifying the leakage position. Thereby, the leak position specifying device 2000 can further reduce the energy consumed by the vibration measuring device 3000 used for specifying the leak position.

[Embodiment 3]
<Overview>
FIG. 7 is a block diagram showing a leakage position specifying system 5000 according to this embodiment. Here, the internal configurations of the leakage position specifying device 2000 and the vibration measuring device 3000 are the same as those in the first embodiment or the second embodiment unless otherwise specified. Therefore, in FIG. 7, the internal configuration of the leakage position specifying device 2000 and the vibration measuring device 3000 is omitted.

  In the present embodiment, each vibration measuring device 3000 belongs to one of n groups. Here, n is an integer of 2 or more. Between two adjacent vibration measurement devices 3000 belonging to the same group, there are n−1 vibration measurement devices 3000 belonging to other groups. Here, “two vibration measurement devices 3000 belonging to the same group are adjacent to each other” means another vibration belonging to the same group as the two vibration measurement devices 3000 between the two vibration measurement devices 3000. It means that the measuring device 3000 is not installed.

  FIG. 8 is a diagram conceptually showing a state in which a plurality of vibration measuring devices 3000 are divided into a plurality of groups. In FIG. 8, each vibration measuring device 3000 is installed along the extending direction of the pipe 10. Each vibration measuring device 3000 belongs to either group 1 or group 2. The numbers written inside each vibration measuring device 3000 represent the number of the group to which each vibration measuring device 3000 belongs. In this case, the vibration measuring device 3000-1, the vibration measuring device 3000-3, and the vibration measuring device 3000-5 belong to the group 1. On the other hand, the vibration measuring device 3000-2, the vibration measuring device 3000-4, and the vibration measuring device 3000-6 belong to the group 2. Between the vibration measurement device 3000-1 and the vibration measurement device 3000-3 belonging to the group 1, there are (2-1) vibration measurement devices 3000 belonging to the group 2, that is, one.

  The measurement execution unit 3020 of the vibration measurement device 3000 belonging to each group repeatedly operates at a different time point or at a different period from the measurement execution unit 3020 of the vibration measurement device 3000 belonging to a different group.

  FIG. 9 is a graph conceptually showing a case where the vibration measuring device 3000 operates at a different time from the vibration measuring device 3000 belonging to another group. In the example of FIG. 9, each vibration measuring device 3000 belongs to either group 1 or group 2. The upper graph in FIG. 9 shows a point in time when the measurement execution unit 3020 of the vibration measurement device 3000 belonging to the group 1 operates. On the other hand, the lower graph of FIG. 9 shows a point in time when the measurement execution unit 3020 of the vibration measurement device 3000 belonging to the group 2 operates.

  As shown in the graph, after the time t has elapsed since the measurement execution unit 3020 of each vibration measurement device 3000 in the group 1 operates, the measurement execution unit 3020 of each vibration measurement device 3000 in the group 2 operates. Then, after the time t has elapsed since the measurement execution unit 3020 of each vibration measurement device 3000 in the group 2 operates, the measurement execution unit 3020 of the vibration measurement device 3000 belonging to the group 1 operates. In this way, the measurement of the vibration measurement device 3000 belonging to each of the other n−1 groups from the time when the measurement execution unit 3020 of the vibration measurement device 3000 belonging to each group operates once to the next operation. The execution unit 3020 operates once at a time.

  There are various periods in which the measurement execution unit 3020 of the vibration measurement device 3000 of each group operates. For example, after the measurement execution unit 3020 of the vibration measurement device 3000 belonging to a certain group operates once and before it operates again, the measurement execution unit 3020 of each vibration measurement device 3000 belonging to each of all other groups is once. It works one by one. This corresponds to the case of the above example using FIG.

  FIG. 10 is a graph conceptually showing a case where the vibration measuring device 3000 operates at a different period from the vibration measuring device 3000 belonging to another group. The graph of FIG. 10 shows an example in which the measurement execution unit 3020 of the vibration measurement device 3000 belonging to group 1 operates at a cycle of 2t, and the measurement execution unit 3020 of the vibration measurement device 3000 belonging to group 2 operates at a cycle of 3t. . By doing in this way, for example, it becomes possible to increase the frequency at which the measurement execution unit 3020 of the vibration measuring device 3000 operates in a group including the vibration measuring device 3000 installed in an aging part of the piping. . By doing so, the leakage position specifying device 2000 can reduce the energy consumption of the vibration measuring device 3000 while discovering leakage in the piping at an early stage.

  The vibration measurement device 3000 may operate at a different time and at a different period from the vibration measurement device 3000 belonging to another group.

  The leak position specifying device 2000 of the present embodiment performs the same operation as the leak position specifying device 2000 of the first or second embodiment.

<Action and effect>
With the above configuration, according to the present embodiment, each vibration measuring device 3000 belongs to one of n groups. Between two adjacent vibration measurement devices 3000 belonging to the same group, there are n−1 vibration measurement devices 3000 belonging to other groups. The measurement execution unit 3020 of the vibration measurement device 3000 belonging to each group repeatedly operates at a different time point or at a different period from the measurement execution unit 3020 of the vibration measurement device 3000 belonging to a different group. By doing in this way, when the leak in piping arises, the frequency which each vibration measuring device 3000 operates can be made low, discovering a leak early. Thereby, the leakage position specifying system 5000 can reduce the energy consumed by the vibration measuring device 3000.

  As mentioned above, although embodiment of this invention was described with reference to drawings, these are illustrations of this invention, The combination of the said embodiment and various structures other than the said embodiment can also be employ | adopted.

Hereinafter, examples of the reference form will be added.
1. A leak position specifying device for specifying a leak position of a fluid in the pipe using a plurality of vibration measuring devices installed in the pipe,
The vibration measuring device has a measurement execution means for measuring vibration at a different time from other adjacent vibration measuring devices,
The leakage position specifying device includes:
A first measuring device specifying means for specifying, as a first measuring device, the vibration measuring device that has measured the vibration that satisfies the predetermined condition among the plurality of vibration measuring devices;
A second measuring device specifying means for specifying any one of the vibration measuring devices as the second measuring device among the two vibration measuring devices adjacent to the first measuring device;
Based on the installation positions of the first measurement device and the second measurement device, position specifying means for specifying a leakage position in the pipe;
Leakage locating device having
2. 1. The leakage position specifying device according to claim 1,
The vibration measuring device further includes a stopping unit that stops an operation in response to an instruction from the leakage position specifying device, and is connected to be able to communicate with the leakage position specifying device.
The leakage position specifying device stops operation with respect to each vibration measuring device that is not adjacent to the first measuring device specified by the first measuring device specifying means before specifying the second measuring device. A leakage position specifying device further comprising stop instruction means for transmitting an instruction to perform.
3. 1. Or 2. The leakage position specifying device according to claim 1,
The second measurement position specifying means uses, as the second measurement device, the vibration measurement device having a greater degree of leakage indicated by the measured vibration among the two vibration measurement devices adjacent to the first measurement device. Identify,
Leak location device.
4). 1. To 3. The leakage position specifying device according to any one of the above,
The position specifying means specifies that the gap between the installation position of the first measurement device and the installation position of the second measurement device is a leakage position in the pipe.
Leak location device.
5. A leakage position specifying system comprising a plurality of vibration measuring devices installed in a pipe, and a leak position specifying device for specifying a fluid leak position in the pipe using the plurality of vibration measuring devices,
The vibration measuring device has a measurement execution means for measuring vibration at a different time from other adjacent vibration measuring devices,
The leakage position specifying device includes:
A first measuring device specifying means for specifying, as a first measuring device, the vibration measuring device that has measured the vibration that satisfies the predetermined condition among the plurality of vibration measuring devices;
A second measuring device specifying means for specifying one of the two vibration measuring devices adjacent to the first measuring device as the second measuring device;
Based on the installation positions of the first measurement device and the second measurement device, position specifying means for specifying a leakage position in the pipe;
Leakage location system having
6). 5. A leak location system described in
The vibration measuring device further includes a stopping unit that stops an operation in response to an instruction from the leakage position specifying device, and is connected to be able to communicate with the leakage position specifying device.
The leakage position specifying device further includes stop instruction means for transmitting an instruction to stop the operation to each of the vibration measuring devices not adjacent to the first measuring device before specifying the second measuring device. Having a leak location system.
7). 5. Or 6. A leak location system described in
The plurality of vibration measuring devices are divided into n groups (n is an integer of 2 or more),
Between the two adjacent vibration measurement devices that belong to the same group, there are n−1 vibration measurement devices belonging to other groups,
The leakage position specifying system in which the measurement execution unit of the vibration measurement device belonging to each group repeatedly operates at a different time point from the measurement execution unit of each vibration measurement device belonging to the other group.
8). 7). A leak location system described in
The measurement execution unit of the vibration measurement device belonging to each group performs the measurement of each of the vibration measurement devices belonging to each of the other n−1 groups during a period from the first operation to the next operation. Leakage location identification system in which the execution means operates once.
9. 7). A leak location system described in
The leak position specifying system in which the cycle in which the measurement execution unit of the vibration measurement device belonging to the group operates is different for each group.
10. 5. Or 6. A leak location system described in
The plurality of vibration measuring devices are divided into n groups (n is an integer of 2 or more),
Between the two adjacent vibration measurement devices that belong to the same group, there are n−1 vibration measurement devices belonging to other groups,
The leakage position specifying system in which the measurement execution unit of the vibration measurement device belonging to each group repeatedly operates at a different period from the measurement execution unit of each vibration measurement device belonging to another group.
11. 5. To 10. A leak location system according to any one of the above,
The second measurement position specifying means uses, as the second measurement device, the vibration measurement device having a greater degree of leakage indicated by the measured vibration among the two vibration measurement devices adjacent to the first measurement device. Identify,
Leak location system.
12 5. To 11. A leak location system according to any one of the above,
The position specifying means specifies that the gap between the installation position of the first measurement device and the installation position of the second measurement device is a leakage position in the pipe.
Leak location system.
13. A leakage position specifying program for causing a computer to function as a leakage position specifying device for specifying a leakage position of fluid in the pipe using a plurality of vibration measuring devices installed in the pipe,
The vibration measuring device has a measurement execution means for measuring vibration at a different time from other adjacent vibration measuring devices,
The leakage location specifying program is stored in the computer.
A first measurement device specifying function for specifying, as a first measurement device, the vibration measurement device that has measured vibrations that satisfy a predetermined condition among the plurality of vibration measurement devices;
A second measurement device specifying function for specifying one of the vibration measurement devices as the second measurement device among the two vibration measurement devices adjacent to the first measurement device;
Based on the installation position of the first measuring device and the second measuring device, a position specifying function for specifying a leak position in the pipe;
Leakage location identification program.
14 13. The leak location program described in
The vibration measuring apparatus further includes a stopping unit that stops an operation in response to an instruction from the computer, and is connected to be communicable with the computer.
The leakage position specifying program is for the vibration measuring devices that are not adjacent to the first measuring device specified by the first measuring device specifying means before specifying the second measuring device to the computer. A leakage position specifying program further having a stop instruction function for transmitting an instruction to stop the operation.
15. 13. Or 14. The leak location program described in
The second measurement position specifying function uses, as the second measurement device, the vibration measurement device having a greater degree of leakage indicated by the measured vibration among the two vibration measurement devices adjacent to the first measurement device. Identify,
Leak location program.
16. 13. To 15. A leakage location identification program according to any one of the above,
The position specifying function specifies that a gap between an installation position of the first measurement device and an installation position of the second measurement device is a leakage position in the pipe.
Leak location program.
17. A leak position specifying system control program for providing a leak position specifying system having a plurality of vibration measuring devices installed in a pipe and a leak position specifying apparatus to have a function of specifying a leak position in the pipe,
The vibration measurement device has a measurement execution function for measuring vibration at a different time from other adjacent vibration measurement devices,
In the leak location device,
A first measurement device specifying function for specifying, as a first measurement device, the vibration measurement device that has measured vibrations that satisfy a predetermined condition among the plurality of vibration measurement devices;
A second measurement device specifying function for specifying one of the vibration measurement devices as the second measurement device among the two vibration measurement devices adjacent to the first measurement device;
Based on the installation position of the first measurement device and the second measurement device, a position specifying function for specifying a leakage position in the pipe;
Leakage position identification system control program.
18. 17. A leakage location specifying system control program according to claim 1,
The leakage position specifying device and the vibration measuring device are connected to be communicable,
The leak location system control program is
The vibration measuring device further has an operation stop function for stopping the operation in response to an instruction from the leakage position specifying device,
A stop instruction function for causing the leakage position specifying device to transmit an instruction to stop the operation to each of the vibration measuring devices that are not adjacent to the first measuring device before specifying the second measuring device; Leakage location identification system control program.
19. 17. Or 18. A leakage location specifying system control program according to claim 1,
The plurality of vibration measuring devices are divided into n groups (n is an integer of 2 or more),
Between the two adjacent vibration measurement devices that belong to the same group, there are n−1 vibration measurement devices belonging to other groups,
The leakage position specifying system control program is a leakage position specifying system control program for causing the vibration measuring device to have a function of repeatedly operating at different time points from the vibration measuring devices belonging to the other groups.
20. 19. A leakage location specifying system control program according to claim 1,
When the vibration measurement device is operated once, the measurement execution unit of each vibration measurement device belonging to each of the other n−1 groups is operated once and then the next operation is performed. Leakage position identification system control program.
21. 19. A leakage location specifying system control program according to claim 1,
A leakage position specifying system control program for causing the vibration measurement device to have a function of operating the measurement execution means of the vibration measurement device belonging to a group to be different for each group.
22. 17. Or 18. A leakage location specifying system control program according to claim 1,
The plurality of vibration measuring devices are divided into n groups (n is an integer of 2 or more),
Between the two adjacent vibration measurement devices that belong to the same group, there are n−1 vibration measurement devices belonging to other groups,
The leakage position specifying system control program is a leakage position specifying system control program for causing the vibration measuring device to have a function of repeatedly operating at a different period from each of the vibration measuring devices belonging to the other group.
23. 17. Thru 22. A leakage location specifying system control program according to any one of the above,
The second measurement position specifying function uses, as the second measurement device, the vibration measurement device having a greater degree of leakage indicated by the measured vibration among the two vibration measurement devices adjacent to the first measurement device. Identify,
Leak location system control program.
24. 17. Thru 23. A leakage location specifying system control program according to any one of the above,
The position specifying function specifies that a gap between an installation position of the first measurement device and an installation position of the second measurement device is a leakage position in the pipe.
Leak location system control program.
25. A leak position specifying method for specifying a fluid leak position in the pipe using a plurality of vibration measuring devices installed in the pipe, which is executed by a computer,
The vibration measuring device has a measurement execution means for measuring vibration at a different time from other adjacent vibration measuring devices,
The leak location method is
A first measuring device specifying step for specifying, as the first measuring device, the vibration measuring device that has measured the vibration satisfying a predetermined condition among the plurality of vibration measuring devices;
A second measuring device specifying step of specifying any one of the vibration measuring devices as the second measuring device among the two vibration measuring devices adjacent to the first measuring device;
A position specifying step for specifying a leak position in the pipe based on an installation position of the first measuring device and the second measuring device;
Leakage location identification method.
26. 25. A method for identifying a leakage position described in
The vibration measuring apparatus further includes a stopping unit that stops an operation in response to an instruction from the computer, and is connected to be communicable with the computer.
The leakage position specifying method stops the operation of each vibration measuring device that is not adjacent to the first measuring device specified by the first measuring device specifying step before specifying the second measuring device. A leakage position specifying method further comprising a stop instruction step of transmitting an instruction to perform.
27. 25. Or 26. A method for identifying a leakage position described in
In the second measurement position specifying step, the vibration measurement device having a greater degree of leakage indicated by the measured vibration among the two vibration measurement devices adjacent to the first measurement device is defined as the second measurement device. Identify,
Leak location method.
28. 25. Thru 27. A leakage position identification method according to any one of the above,
The position specifying step specifies that a gap between an installation position of the first measurement device and an installation position of the second measurement device is a leakage position in the pipe.
Leak location method.
29. A leak position specifying method in which a leak position specifying system having a plurality of vibration measuring devices installed in a pipe and a leak position specifying apparatus specifies a leak position in the pipe,
A measurement execution step in which the vibration measurement device measures vibration at a different time from other adjacent vibration measurement devices;
A first measuring device specifying step for specifying, as the first measuring device, the vibration measuring device that measures the vibration satisfying a predetermined condition in the measurement execution step among the plurality of vibration measuring devices;
A second measuring device specifying step in which the leakage position specifying device specifies one of the vibration measuring devices as the second measuring device among the two vibration measuring devices adjacent to the first measuring device;
A position specifying step in which the leak position specifying device specifies a leak position in the pipe based on an installation position of the first measuring device and the second measuring device;
Leakage location identification method.
30. 29. A method for identifying a leakage position described in
The leakage position specifying device and the vibration measuring device are connected to be communicable,
The leak location method is
The vibration measuring device receives an instruction from the leakage position specifying device and stops the operation, and
When the leakage position specifying device specifies the first measuring device, the operation is stopped for each vibration measuring device that is not adjacent to the first measuring device before specifying the second measuring device. A stop instruction step for transmitting an instruction to perform,
A leak location method further comprising:
31. 29. Or 30. A method for identifying a leakage position described in
The plurality of vibration measuring devices are divided into n groups (n is an integer of 2 or more),
Between the two adjacent vibration measurement devices that belong to the same group, there are n−1 vibration measurement devices belonging to other groups,
The leakage position specifying method further includes a step in which the vibration measuring device repeatedly operates at a time different from each vibration measuring device belonging to the other group.
32. 31. A method for identifying a leakage position described in
The measurement execution step of each of the vibration measurement devices includes the measurement execution step of each of the vibration measurement devices belonging to each of the other n−1 groups from one operation to the next operation. A leak location method that works once at a time.
33. 31. A method for identifying a leakage position described in
The leak position specifying method in which the cycle in which the measurement execution step of the vibration measuring device belonging to the group operates is different for each group.
34. 29. Or 30. A method for identifying a leakage position described in
The plurality of vibration measuring devices are divided into n groups (n is an integer of 2 or more),
Between the two adjacent vibration measurement devices that belong to the same group, there are n−1 vibration measurement devices belonging to other groups,
The leakage position specifying method further includes a step in which the vibration measuring device repeatedly operates at a different period from each of the vibration measuring devices belonging to the other group.
35. 29. Thru 34. A leakage position identification method according to any one of the above,
In the second measurement position specifying step, the vibration measurement device having a greater degree of leakage indicated by the measured vibration among the two vibration measurement devices adjacent to the first measurement device is defined as the second measurement device. Identify,
Leak location method.
36. 29. Thru 35. A leakage position identification method according to any one of the above,
The position specifying step specifies that a gap between an installation position of the first measurement device and an installation position of the second measurement device is a leakage position in the pipe.
Leak location method.

  This application claims the priority on the basis of Japanese application Japanese Patent Application No. 2012-215798 for which it applied on September 28, 2012, and takes in those the indications of all here.

Claims (10)

A leak position specifying device for specifying a leak position of a fluid in the pipe using a plurality of vibration measuring devices installed in the pipe,
The vibration measuring device has a measurement execution means for measuring vibration at a different time from other adjacent vibration measuring devices,
The leakage position specifying device includes:
Among the plurality of vibration measuring devices, a first measuring device specifying unit that specifies the vibration measuring device that has measured the vibration indicating the leakage of the pipe as the first measuring device among the plurality of vibration measuring devices;
Of the two vibration measurement devices adjacent to the first measurement device, the second measurement device specifies the vibration measurement device having a greater degree of leakage indicated by the vibration measured by the measurement execution unit as the second measurement device. Device identification means;
Position specifying means for specifying that the position between the installation position of the first measurement device and the installation position of the second measurement device is a leakage position in the pipe;
Leakage locating device having The leakage position specifying device according to claim 1,
The vibration measuring device further includes a stopping unit that stops an operation in response to an instruction from the leakage position specifying device, and is connected to be able to communicate with the leakage position specifying device.
The leakage position specifying device stops operation with respect to each vibration measuring device that is not adjacent to the first measuring device specified by the first measuring device specifying means before specifying the second measuring device. A leakage position specifying device further comprising stop instruction means for transmitting an instruction to perform. A leakage position specifying system comprising a plurality of vibration measuring devices installed in a pipe, and a leak position specifying device for specifying a fluid leak position in the pipe using the plurality of vibration measuring devices,
The vibration measuring device has a measurement execution means for measuring vibration at a different time from other adjacent vibration measuring devices,
The leakage position specifying device includes:
Among the plurality of vibration measuring devices, a first measuring device specifying unit that specifies the vibration measuring device that has measured the vibration indicating the leakage of the pipe as the first measuring device among the plurality of vibration measuring devices;
Of the two vibration measurement devices adjacent to the first measurement device, the second measurement device specifies the vibration measurement device having a greater degree of leakage indicated by the vibration measured by the measurement execution unit as the second measurement device. Device identification means;
Position specifying means for specifying that the position between the installation position of the first measurement device and the installation position of the second measurement device is a leakage position in the pipe;
Leakage location system having The leak location system according to claim 3 ,
The vibration measuring device further includes a stopping unit that stops an operation in response to an instruction from the leakage position specifying device, and is connected to be able to communicate with the leakage position specifying device.
The leakage position specifying device stops operation with respect to each vibration measuring device that is not adjacent to the first measuring device specified by the first measuring device specifying means before specifying the second measuring device. A leakage position specifying system further comprising stop instruction means for transmitting an instruction to perform. The leak location system according to claim 3 or 4 ,
The plurality of vibration measuring devices are divided into n groups (n is an integer of 2 or more),
Between the two adjacent vibration measurement devices that belong to the same group, there are n−1 vibration measurement devices belonging to other groups,
The leakage position specifying system in which the measurement execution unit of the vibration measurement device belonging to each group repeatedly operates at a different time point from the measurement execution unit of each vibration measurement device belonging to the other group. The leak location system according to claim 5 ,
The measurement execution unit of the vibration measurement device belonging to each group performs the measurement of each of the vibration measurement devices belonging to each of the other n−1 groups during a period from the first operation to the next operation. Leakage location identification system in which the execution means operates once. The leak location system according to claim 5 ,
The leak position specifying system in which the cycle in which the measurement execution unit of the vibration measurement device belonging to the group operates is different for each group. The leak location system according to claim 3 or 4 ,
The plurality of vibration measuring devices are divided into n groups (n is an integer of 2 or more),
Between the two adjacent vibration measurement devices that belong to the same group, there are n−1 vibration measurement devices belonging to other groups,
The leakage position specifying system in which the measurement execution unit of the vibration measurement device belonging to each group repeatedly operates at a different period from the measurement execution unit of each vibration measurement device belonging to another group. A leakage position specifying program for causing a computer to function as a leakage position specifying device for specifying a leakage position of fluid in the pipe using a plurality of vibration measuring devices installed in the pipe,
The vibration measuring device has a measurement execution means for measuring vibration at a different time from other adjacent vibration measuring devices,
The leakage location specifying program is stored in the computer.
A first measurement device specifying function for specifying, as the first measurement device, the vibration measurement device in which the measurement execution unit measures vibration indicating leakage of the pipe among the plurality of vibration measurement devices;
Of the two vibration measurement devices adjacent to the first measurement device, the second measurement device specifies the vibration measurement device having a greater degree of leakage indicated by the vibration measured by the measurement execution unit as the second measurement device. Device specific functions,
A position specifying function for specifying that the position between the installation position of the first measurement device and the installation position of the second measurement device is a leakage position in the pipe;
Leakage location identification program. A leak position specifying method for specifying a fluid leak position in the pipe using a plurality of vibration measuring devices installed in the pipe, which is executed by a computer,
The vibration measuring device has a measurement execution means for measuring vibration at a different time from other adjacent vibration measuring devices,
The leak location method is
A first measuring device specifying step for specifying, as the first measuring device, the vibration measuring device in which the measurement execution unit measures vibration indicating leakage of the pipe among the plurality of vibration measuring devices;
Of the two vibration measurement devices adjacent to the first measurement device , the second measurement device specifies the vibration measurement device having a greater degree of leakage indicated by the vibration measured by the measurement execution unit as the second measurement device. A device identification step;
A position specifying step for specifying that the position between the installation position of the first measurement device and the installation position of the second measurement device is a leakage position in the pipe;
Leakage location identification method.

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