JP2002188978A - Monitoring system, and sound wave transmitter/receiver - Google Patents

Abstract

PROBLEM TO BE SOLVED: To detect gas leak in gas piping, to surely notify a center of information on the gas leak, and to reduce a cost, resources or the like required for useless exchange of the gas piping. SOLUTION: A sound wave reception element 33-1 receives a sound wave signal S1 generated from a gas leak spot L1. A leak signal processing part 37-1 determines a variation between the received signal and a reception signal in the case of no gas leak. When the variation in some frequency specific region is over a threshold and the state over the threshold continues as long as a prescribed time, it is determined that 'a gas leak exists'. The determination result is transmitted as a sound wave signal S2 through piping 5-1, received by this sound wave transmitter/receiver 8, and transmitted to the center 15 through an NCU 11, and a public network 13.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a monitoring system for monitoring a gas leak in a pipe carrying gas such as a gas pipe.

[0002]

2. Description of the Related Art Conventionally, as a method of detecting gas pipe leakage, an electronic gas meter equipped with various sensors and a microcomputer is connected to a telephone line, and a pointer value and gas leak information can be remotely or remotely transmitted in a wired or wireless manner. There is a method to notify the center. In addition, the gas piping was replaced after deemed to have deteriorated after a predetermined number of years.

[0003]

However, the method using a gas meter has a problem that only gas leakage downstream of the gas meter can be detected. When reporting gas leak information in a wired manner, there is a problem that wiring is difficult, especially in an apartment house, and the cost of laying wiring increases. When reporting gas leak information in a wireless manner, a gas meter is often installed in a metal box in an apartment house or the like, and there is also a problem that radio waves used for reporting do not arrive. Further, when replacing gas pipes, many of the pipes to be replaced do not actually leak gas due to deterioration, and this leads to wasteful consumption of resources and costs.

The present invention has been made in view of such a problem, and an object of the present invention is to detect a gas leak upstream of a gas meter and surely report information on the gas leak to a center so that resources and resources can be obtained. It is to provide a monitoring system for reducing costs.

[0005]

According to a first aspect of the present invention, there is provided at least one first sound wave transceiver provided in a gas pipe, wherein the first sound wave transceiver is provided. The transceiver includes a receiving unit that receives a first sound wave signal generated at the time of gas leakage of the gas pipe, and a determining unit that determines presence or absence of gas leakage from an output of the receiving unit. It is a monitoring system. In the first invention,
The sound wave transmitter / receiver receives a sound wave signal generated at the time of gas leakage, and determines the presence or absence of gas leakage from the signal. According to a second aspect of the present invention, a plurality of sound wave transceivers are provided in a gas pipe, wherein the sound wave transceiver receives a first sound wave signal generated when gas leaks from the gas pipe, and an output of the reception means. Determining means for determining the presence or absence of gas leakage from, and a monitoring system characterized by comprising any one of the plurality of sound wave transceivers detecting the presence or absence of gas leakage to identify a gas leakage location is there. In the second invention, a plurality of sound wave transceivers are installed in a gas pipe, and a sound wave signal generated at the time of gas leakage is received. It detects the presence or absence of leakage and specifies the location of gas leakage. A third invention is provided in a gas pipe,
A sound wave receiving means, a second sound wave receiving means, an estimating means for estimating a position of a gas leak point in a gas pipe from a sound wave signal received by the first sound wave receiving means and the second sound wave receiving means, It is a sound wave transmitter / receiver characterized by comprising: A fourth invention includes a plurality of detecting means for detecting gas leakage of the gas pipe, and a center for receiving a leak information signal sent from the plurality of detecting means, wherein the center is one of the plurality of detecting means. The monitoring system is characterized in that a gas leak location is identified by recognizing which detection means has sent a leak information signal. In the fourth invention, the center identifies the gas leak location by recognizing which of the plurality of detecting means has sent the leak information signal.
Here, the detecting means is a sound wave transceiver including a receiving means for receiving a first sound wave signal generated at the time of gas leakage of the gas pipe, and a judging means for judging the presence or absence of gas leakage from the output of the receiving means. Have.

[0006]

Embodiments of the present invention will be described below in detail with reference to the drawings. FIG. 1 is a schematic configuration diagram of a monitoring system 1 according to an embodiment of the present invention.

[0007] The monitoring system 1 includes a sound wave transceiver (slave unit).
7-1, 7-2, 7-3, 7-4, 7-5, 7-6, sound wave transceiver (master unit) 8, gas meters 9-1, 9-2, 9
-3, 9-4, 9-5, 9-6, network controller (NC
U) 11, a public line 13, a center 15, and the like.

Houses 2-1, 2-2, 2-3, 2-4, 2
Reference numerals -5 and 2-6 denote individual housing units of apartment houses such as condominiums. The sound wave transmitter / receiver 7-1 and the gas meter 9-1 are in a house 2-
1 and connected to the gas pipe 5-1. The sound wave transceiver 7-2 and the gas meter 9-2 are installed in the house 2-2, and the sound wave transceiver 7-3 and the gas meter 9-3 are installed in the house 2-3, and are similarly connected to the gas pipe 5-1.

The sound wave transmitter / receiver 7-4 and the gas meter 9-4 are installed in the house 2-4 and connected to the gas pipe 5-2.
The sound wave transceiver 7-5 and the gas meter 9-5 are house 2-5.
The sound wave transmitter / receiver 7-6 and the gas meter 9-6 are connected to the house 2-
6 and connected to a gas pipe 5-2.

The gas pipes 5-1 and 5-2 are connected to the main pipe 3. In the gas pipes 5-1 and 5-2 and the main pipe 3, the sound wave transceiver 8 is located at an optimum position for receiving signals from the sound wave transceivers 7-1, 7-2,..., 7-6. Will be installed. For example, the sound wave transmitter / receiver 8 includes the gas pipe 5-1 and the main pipe 3
It is installed near the branch point with.

The sound wave transceiver 8 is provided with a network controller (NC).
U) 11 and connected to the center 15 via the public line 13.
Connected to. Sound wave transceivers 7-1, 7-2, ..., 7-
6 is referred to as a slave, and the sound wave transceiver 8 is referred to as a master or base station. , 7-6 and the sound wave transceiver 8, transmission and reception of information relating to gas leak detection and meter reading by the gas meters 9-1, 9-2, ..., 9-6. Transmission and reception of information related to processing and the like are performed.

The sound wave transceivers 7-1, 7-2,..., 7-6 and the sound wave transceiver 8 in the gas leak detection processing are described below.
Will be described. FIG. 2 is a block diagram showing the structure of the sound wave transceiver 7-2 and the sound wave transceiver 8. The sound wave transceiver 7-2 is a sound wave transmitting element (speaker)
23-1, power amplifier 25-1, communication signal processing unit 27
-1, an acoustic wave receiving element (microphone) 33-1, an amplifier / filter (bandpass filter) 35-1, a leak signal processing unit 37-1, and the like. In addition, other sound wave transceivers 7-1 and 7
-3, 7-4, 7-5, and 7-6 have the same structure.

The sound wave receiving element 33- of the sound wave transceiver 7-2
1 receives a sound wave signal S1 generated when gas leaks from the gas leak location L1.

The amplifier / filter 35-1 extracts a predetermined band from the received sound wave signal S1 and amplifies it.
The leak signal processing unit 37-1 performs processing and determination of the received signal, and transmits a leak detection signal to the communication signal processing unit 27-1 when it is determined that “there is a gas leak”.

The communication signal processor 27-1 processes the gas leak detection signal to generate a leak information signal. This leak information signal is amplified by the power amplifier 25-1 and is converted into a sound signal S2 by the sound wave transmitting element 23-1 in the pipe 5-1.
Is transmitted to the sound wave transmitter / receiver 8.

The sound wave transceiver 8 includes a sound wave transmitting element (speaker) 23-2, a power amplifier 25-2, a communication signal processing unit 27-2, a sound wave receiving element (microphone) 33-2, an amplifier
It has a filter (bandpass filter) 35-2, a leak signal processing unit 37-2, and the like.

The function of each part of the sound wave transmitter / receiver 8 is the same as that of the sound wave transmitter / receiver 7-2, but the communication signal processor 27-2 is connected to the NCU 11, and the NCU 11, the public line 1
Signals and the like are transmitted to and received from the center 15 via the communication terminal 3.

The sound wave receiving element 33-2 receives the sound wave signal S2, which is a leak information signal, the amplifier / filter 35-2 amplifies the received signal, and the received signal is transmitted to the communication signal processing unit 27.
-2. The communication signal processing unit 27-2 converts the received signal into a specific signal, and transmits the signal to the center 15 via the NCU 11 and the public line 13. Thus, the gas pipe 5-
1 is transmitted to the center 15.

Next, a case will be described in which information regarding the meter reading process is transmitted and received by the gas meter 9-2 between the sound wave transceivers 7 and 8. Telegrams such as meter reading instructions sent from the center 15 are sent to the public line 13, the NCU.
11 to the communication signal processing unit 27-2. The communication signal processing unit 27-2 converts the message into a specific signal, and then sends the signal to the power amplifier 25-2, where the power amplifier 25-2
2 and is converted to a sound wave signal by the sound wave transmitting element 23-2 and transmitted to the pipe 5-1.

The sound wave signal obtained by converting a telegram such as a meter reading command is
The signal is received by the sound wave receiving element 33-1 of the sound wave transceiver 7-2, and the received signal is amplified by the amplifier filter 35-1 and sent to the communication signal processing unit 27-1. Communication signal processing unit 27
-1 processes the signal, and sends a meter reading information signal such as a meter value of the gas meter 9-2 to the center 15.

The communication signal processing unit 27-1 sends, for example, a meter reading information signal to the power amplifier 25-1, and the power amplifier 25-1 amplifies the meter reading information signal and outputs the sound wave transmitting element 23-.
Send to 1. This electric signal is converted into a sound wave signal by the sound wave transmitting element 23-1, and the sound wave signal is sent to the sound wave transceiver 8, where the NCU 11 and the public line 13 are used.
Conveyed to. In this way, the meter reading information signal relating to the meter reading of the gas meter 9-2 is also transmitted to the center 15 using the sound wave transmitting and receiving device 7-2 and the sound wave transmitting and receiving device 8.

Next, a process of judging the presence or absence of gas leakage by the monitoring system 1 when gas leaks from the gas leakage point L1 in the pipe 5-1 will be described. FIG.
5 is a flowchart showing a first method for determining gas leakage. The sound wave receiving element (microphone) 33-1 has a sound wave signal S1.
Is received (step 301).

The received signal is passed through a band-pass filter 35-1 (step 302) to amplify a signal in a specific frequency band. Since the received signal contains noise and the like, the signal is passed through a band-pass filter to remove stationary noise whose frequency band is known.

A variation between a signal output in a specific frequency region and a signal output when there is no gas leakage is obtained (step 30).
3), determine whether the variation exceeds a threshold (step 304).

If the variation exceeds the threshold value, it is determined whether the state exceeding the threshold value continues for a predetermined time or more (step 3).
05) If it continues for a certain period of time or more, it is determined that "gas leaks" (step 306). These determination processes are performed by the leak signal processing unit 37-1.

In step 305, the output due to sudden noise or the like is removed. If the variation does not exceed the threshold value or the duration of the state where the variation exceeds the threshold value is short, the process returns to step 301 to receive the sound wave signal S1 again.

The determination that "there is a gas leak" is transmitted to the sound wave transmitter / receiver 8 by the sound wave S2 as described above.
The information is transmitted to the center 15 via the CU 11 and the public line 13. Here, the gas leak determination process is performed by the sound wave transceiver 7-2, but the other sound wave transceivers 7-1 and 7
Any of -3, 7-4, 7-5, and 7-6 may be used.

In the first gas leakage determination method shown in FIG. 3, by superimposing the signals passed through the band-pass filters of different frequency bands in step 302, the determination accuracy is further improved. Sound signal S1 generated when gas leaks
May resonate depending on the piping configuration or embedding conditions, and the frequency band in which the signal output increases is also different for each piping configuration.
Therefore, passing through band-pass filters having different frequency band characteristics makes it easier to detect a frequency band having a large output.

Although the case where the sound wave transceiver 7-2 is used has been described in the determination method shown in FIG. 3, a sound wave signal is transmitted using a plurality of sound wave transceivers, for example, sound wave transceivers 7-1 and 7-6. When S1 is received and the same gas leak determination is performed, the determination accuracy is increased.

Next, a second method shown in FIG. 4 for determining gas leakage will be described. The sound wave receiving element (microphone) 33-1 receives the sound wave signal S1 (step 40).
1). The leakage signal processing unit 37-1 performs a Fourier transform (FFT) process on the received signal, obtains a frequency spectrum of the received signal, and obtains a sound pressure level (step 402).

The sound pressure level when there is no gas leakage is compared with the sound pressure level of the received signal obtained in step 402 (step 403). At this time, it is determined whether or not the sound pressure level is equal to or higher than a threshold value in a specific frequency band (step 404), and it is determined whether or not the state in which the sound pressure level is equal to or higher than the threshold value continues for a predetermined time (step 405). Here, if the sound pressure level equal to or higher than the threshold value continues for a predetermined time or more, it is determined that "gas leaks" (step 405).

FIG. 5 is a diagram showing an example of the sound pressure level when there is no gas leakage and the sound pressure level of a signal at the time of gas leakage. For example, in FIG. 5, the frequency band is 2000 [Hz].
The sound pressure level of “with gas leak” is higher than the sound pressure level of “without gas leak” between 8000 and 4000 [Hz]. At this time, it is determined whether or not the sound pressure level of “gas leak” is equal to or higher than the threshold value, and if the sound pressure level of the specific area is equal to or higher than the threshold value for a certain period of time, “gas leak is detected” Is determined.

In the second determination method, the reason why the sound pressure level is limited to a specific frequency band is to remove an output due to a continuous external noise, a sudden noise or the like. If the sound pressure level does not exceed the threshold value or the duration of the state where the sound pressure level exceeds the threshold value is short, the process returns to step 401 to receive the sound wave signal S1 again.

The determination that "there is a gas leak" is transmitted to the sound wave transmitter / receiver 8 by the sound wave S2 as described above.
The information is transmitted to the center 15 via the CU 11 and the public line 13.

In the second leak determination method shown in FIG.
If the sound pressure levels in a plurality of different frequency bands are picked up and compared in step 404, the determination accuracy is further improved. The sound wave signal S1 generated at the time of gas leakage may resonate depending on the piping configuration or embedding conditions, and the frequency band in which the sound pressure level increases also differs for each piping configuration. Therefore, comparing sound pressure levels in different frequency bands makes it easier to detect a frequency band with a large output.

In the determination method shown in FIG. 4, the case where the sound wave transceiver 7-2 is used has been described. However, since the output differs depending on the distance from the place where the sound wave is generated, a plurality of sound wave transceivers, for example, sound wave transceivers, are used. If the sound wave signal S1 is received using 7-1, 7-6, and the like, and the same gas leak determination is performed, the determination accuracy is increased.

As described above, the sound wave signal at the time of gas leakage is received by the sound wave transmitter / receiver 7 provided in the pipe, and the presence or absence of gas leakage is determined by using the first determination means and the second determination means. It is possible.

Since the sound wave transmitter / receiver is easy to install and does not require wiring or the like, gas leakage can be easily detected. Further, the detection result can be reliably transmitted to the center 15 by using the sound wave signal.

Next, a method for detecting the position of a gas leak location in an apartment house will be described. In the apartment house shown in FIG. 1, all the sound wave transceivers 7-1, 7-2, 7
-3,..., 7-6, and a sound wave signal is received by the sound wave receiving element (microphone) of the sound wave transmitter / receiver 8, and the judgment is performed by the above-described first judgment method. The location of the gas leak is estimated from the position of each sound wave transceiver and the magnitude of the variation in the output in the case of "no gas leak".

For example, when the gas leaks at L1 as shown in FIG. 1, the variation of the signals received by the sound wave transceivers 7-1 and 7-2 becomes the largest, and the gas leak location is the sound wave transceiver. It is estimated that it is between the installation location of 7-1 and the sound wave transceiver 7-2.

Similarly, the second determination method may be used. In this case, the location of the gas leak is estimated based on the magnitude of the output of the sound pressure level in the specific frequency region.

Next, a second method for estimating a gas leak location will be described. FIG. 6 is a diagram showing a sound wave transmitter / receiver 71 used in the second gas leak location estimation method. The sound wave transceiver 71 is different from the sound wave transceiver 7 and the sound wave transceiver 8 shown in FIG.
Filters 35-3 and 35-4, leakage processing signal section 37-
3, 37-4. That is, it has a two-channel sound wave receiving unit.

The gas leakage point L3 of the pipe 5-5 shown in FIG.
When the gas leaks from the device, the sound wave receiving element (microphone) 33
Assuming that the received signal received by -3 is f ₁ (t) and the received signal received by the sound wave receiving element (microphone) 33-4 is f ₂ (t), f ₁ (t) = G ₁ · G ′ _1. the _{R (t-t 1) f} 2 (t) = G 2 · G '2 · R (t-t 2).

[0044] In this case, _{G 1} is the gain of the microphone 33-3, G
₂ is a gain of the microphone 33-4. G _'1 is the attenuation due to wave propagation from the gas leakage location L3 to the microphone 33-3, G' ₂ is the attenuation due to wave propagation from the gas leakage location L3 to the microphone 33-4. R (t) is a leak sound wave signal at the leak position at time t, and t ₁ is the microphone 3
Time to reach 3-3, _{t 2} is the time to reach the microphone 33-4.

At this time, the reception signal f of each microphone
₁ (t), normalized cross-correlation function γ of f ₂ (t)
₁₂ (τ) is

(Equation 1) Is defined by To be sufficiently larger than T is a t ₁ and t ₂ in the actual operation, obtaining the cross-correlation function by setting the integration time

[0046] Here, when determining the τp when the cross-correlation function gamma (tau) is a peak, the τp is the time difference between t ₁ and t _2. This time difference and the microphones 33-3 and 33-4
And the distance between the microphones, the direction and position of the gas leakage point L3 are specified. For example, when the gas leakage point L3 is between the microphones 33-3 and 33-4, the position of the gas leakage point L3 is specified from the time difference and the distance between the microphones, and the gas leakage point L3 is connected to the microphone 33-3. Microphone 33-
If the difference is not between 4, the direction of the gas leakage point L3 from the microphones 33-3 and 33-4 is specified by the sign of the time difference. This specific processing is performed by the leak signal processing units 37-3 and 37-4 of the sound wave transceiver 71.

The leak information signal relating to the gas leak position and the like specified in this manner is converted into a communication signal by the communication signal processing unit 27-3, converted into a sound wave signal by the speaker 23-3, and propagated through the pipe 5-5. The information is transmitted to the sound wave transceiver 8 connected to the NCU 11 and transmitted to the center 15.

As described above, by receiving and processing the sound wave signal generated at the time of gas leakage, it is possible to estimate not only the presence or absence of gas leakage but also the position.

Next, a second embodiment will be described. FIG. 7 is a schematic configuration diagram of a monitoring system 101 using the monitoring system 1 described above. As shown in FIG. 7, the center 15 is connected to the house 102-via the public line 13.
1, 102-2, 102-3,.... The house 102-1 is a house 2-1 or 2-2 shown in FIG.
……, represents an apartment house. House 102-2 is a detached house, and house 102-3 is an apartment house.

Then, the houses 102-1, 102-2, 1
02-3,..., The gas meter 9 has a sound wave transmitter / receiver 7.
If a gas leak occurs in the gas pipe 5, a leak information signal is sent to the center 15 via the public line 13. For example, when a gas leak occurs in the house 102-1, a leak information signal is sent to the center 15. Similarly,
If a gas leak occurs in the house 102-2, the center 1
5 is sent a leakage information signal.

The center 15 is connected to any of the houses 102-1,
102-2, 102-3,..., A house having a gas leak depending on whether a leak information signal is sent (for example, house 1)
02-1) is specified.

FIG. 8 is a flowchart showing the processing of the center 15. The center 15 monitors whether a leak information signal is sent (step 701), and when the leak information signal is sent, identifies the house that sent the leak information signal (step 702).

For example, the sound wave transmitter / receiver 8 of the house 102-1
, The center 15 knows that there is a gas leak in the house 102-1. Center 15
Informs the manager of the house 102-1 that there is a gas leak via the public line 13 (step 703).

For this communication, the computer of the center 15 may automatically send a message to the house 102-1 by telephone, or the operator of the center 15 may make a telephone call to the house 102-1. After that, the gas leak location and the like are specified in more detail by the procedure described above in the house 102-1 and the gas pipe 5 is replaced.

As described above, according to the present embodiment, the gas pipe 5 and the like are replaced when a gas leak occurs. And energy saving can be achieved.

The management company that manages and operates the management system 101 is the houses 102-1, 102-2, and 102-3.
And the like, a contract may be made, the gas pipe may be monitored, and a notification about replacement of the gas pipe may be made. In this case, the management company collects a contract fee and the like from the houses 102-1, 102-2, and 102-3.

[0057]

As described above in detail, according to the present invention, a gas leak in a gas pipe is detected, information on the gas leak is reliably reported to the center, and the cost and the cost due to unnecessary replacement of the gas pipe are reduced. Resources and the like can be reduced.

[Brief description of the drawings]

FIG. 1 is a schematic configuration diagram of a monitoring system 1 according to an embodiment of the present invention.

FIG. 2 is a block diagram showing the structure of sound wave transceivers 7 and 8;

FIG. 3 is a flowchart showing a first determination method by the monitoring system 1;

FIG. 4 is a flowchart showing a second determination method by the monitoring system 1;

FIG. 5 is a diagram showing sound pressure levels of “gas leakage” and “no gas leakage”

FIG. 6 is a block diagram showing the structure of a sound wave transceiver 71;

FIG. 7 is a schematic configuration diagram of a monitoring system 101.

FIG. 8 is a flowchart showing processing of a center 15;

[Explanation of symbols]

 1. Monitoring system 2. House 5-1 5-2, 5-3. Piping 7-1, 7-2, 7-6 ... Sound wave transceiver 8. Sound wave Transceiver 9-1, 9-2, 9-6 Gas meter 11 Network controller (NCU) 13 Public line 15 Center

 ──────────────────────────────────────────────────続 き Continued on the front page F term (reference) 2F030 CB02 CC13 2G067 AA14 BB11 CC04 DD13 EE01 EE08 3J071 AA02 BB11 EE06 EE11 EE21 EE31 EE37 FF03 5C086 AA02 BA01 CA09 CB11 DA08

Claims (17)

[Claims] 1. At least one first sound wave transceiver provided in a gas pipe, wherein the first sound wave transceiver transmits a first sound wave signal generated when the gas pipe leaks. A monitoring system comprising: receiving means for receiving; and determining means for determining presence or absence of gas leakage from an output of the receiving means. 2. The determination means obtains a first output of a sound wave signal at the time of gas leakage in a specific frequency region and a second output of a sound wave signal when there is no gas leakage, and determines the first output 2. The monitoring system according to claim 1, wherein it is determined that there is a gas leak when a state in which a variation from the second output is equal to or more than a threshold value continues for a predetermined time or more. 3. The determination means obtains a first frequency characteristic of a sound signal at the time of gas leakage and a second frequency characteristic of a sound signal at the time of no gas leakage, and determines a first frequency characteristic in a specific frequency region. 2. The monitoring system according to claim 1, wherein when a state in which a difference between the frequency characteristic and the second frequency characteristic is equal to or larger than a threshold value continues for a predetermined time or more, it is determined that there is gas leakage. 4. The apparatus according to claim 1, further comprising: means for creating a leak information signal from a result of the determination by the determining means; and means for converting the leak information signal into a second sound wave signal. Monitoring system. 5. The second sound wave signal is transmitted to a second sound wave transceiver via a gas pipe, and is transmitted from the second sound wave transceiver to a center via a public line. Item 5. The monitoring system according to Item 4. 6. The first sound wave transceiver is connected to a gas meter, and the second sound wave transceiver is connected to a center via a public line, and information is transmitted between the center and the gas meter. The monitoring system according to claim 1, wherein the monitoring system is performed. 7. A plurality of sound wave transceivers are provided in a gas pipe, wherein the sound wave transceiver receives a first sound wave signal generated at the time of leakage of the gas pipe, and receives gas from an output of the reception means. A monitoring system comprising: a determination unit configured to determine whether or not there is a leak; and wherein any of the plurality of sound wave transceivers detects the presence or absence of the leak to identify a gas leak location. 8. A gas pipe provided on a gas pipe, based on a first sound wave receiving means, a second sound wave receiving means, and a sound wave signal received by the first sound wave receiving means and the second sound wave receiving means. Estimating means for estimating the position of the gas leak point in the above. 9. The estimating means obtains a cross-correlation function between a first sound wave signal received by the first sound wave receiving means and a second sound wave signal received by the second sound wave receiving means. The acoustic wave transceiver according to claim 5, wherein a gas leak location is estimated. 10. A plurality of detecting means for detecting leakage of a gas pipe, and a center for receiving a leak information signal sent from the plurality of detecting means, wherein the center is any one of the plurality of detecting means. A surveillance system characterized in that a leak location is specified by recognizing whether a leak information signal has been sent from the detecting means. 11. The monitoring system according to claim 10, wherein said detecting means is provided on a house side. 12. The detecting means includes at least one sound wave transceiver provided in a gas pipe, wherein the sound wave transceiver receives a first sound wave signal generated when the gas pipe leaks. The monitoring system according to claim 10, further comprising: a receiving unit configured to determine whether there is a gas leak from an output of the receiving unit. 13. The determination means obtains a first output of a sound wave signal at the time of gas leakage in a specific frequency region and a second output of a sound wave signal when there is no gas leakage, and determines the first output 13. The monitoring system according to claim 12, wherein it is determined that there is a gas leak when a state in which a variation from the second output is equal to or more than a threshold value continues for a predetermined time or more. 14. The determination means obtains a first frequency characteristic of a sound signal at the time of gas leakage and a second frequency characteristic of a sound signal at the time of no gas leakage, and obtains a first frequency characteristic in a specific frequency region. 13. The monitoring system according to claim 12, wherein when a state in which a difference between the frequency characteristic and the second frequency characteristic is equal to or larger than a threshold continues for a predetermined time or more, it is determined that there is gas leakage. 15. The apparatus according to claim 12, further comprising: means for generating a leak information signal from a result of the determination by the determining means; and means for converting the leak information signal into a second sound wave signal. Monitoring system. 16. The second sound wave signal is transmitted to a second sound wave transceiver via a gas pipe, and is transmitted from the second sound wave transceiver to the center through a public line. The monitoring system according to claim 15. 17. The sound wave transceiver is connected to a gas meter, and one of the sound wave transceivers is a second sound wave transceiver connected to a center via a public line, wherein the center includes: The monitoring system according to claim 12, wherein information is transmitted to and from the gas meter.