JP3497048B2 - Gas meter with seismic sensor - Google Patents

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a gas meter having a seismic detector, and more particularly, it detects the seismic vibration of an earthquake having a predetermined seismic intensity or more from the seismic detector, and the optimum shut-off valve according to the frequency of the seismic vibration obtained from the seismic vibration. The present invention relates to a signal processing method for a gas meter and a seismic sensor capable of controlling shutoff and recovery of a gas.

[0002]

2. Description of the Related Art A gas meter provided between a gas supply pipe and an indoor pipe of each home or the like usually has a seismic sensor inside, and the seismic sensor senses a vibration exceeding a certain level and outputs a detection signal. Upon output, the microcomputer analyzes the sensing signal according to a predetermined algorithm and closes the shutoff valve if necessary.

Disasters due to earthquakes are difficult to predict, but at least in the situation where the upstream side of the gas meter is not damaged and gas can be supplied, and when the indoor piping downstream of the gas meter is damaged. , If gas is supplied to the indoor piping after the earthquake, the air and gas may mix, which may cause an explosion at the time of ignition. Therefore, it is required to forcibly close the gas shutoff valve when a strong earthquake occurs.

Conventionally, a seismoscope equipped with a gas meter supplies an output to the microcomputer indicating that the seismic shock has occurred when a seismic vibration of a certain magnitude or more occurs. The microcomputer analyzes the sensed signal according to a predetermined algorithm, and when it determines that it is due to an earthquake, it closes the shutoff valve. In the case of the conventional one-way cutoff valve, the subsequent return is performed manually.

For example, when the seismoscope senses a tremor with a seismic intensity of 5 or more, the sensor output is given as a digital value to the microcomputer in the gas meter, and the microcomputer detects the occurrence of an earthquake. However, the microcomputer usually analyzes whether or not the seismic sensor output is turned on and off according to a predetermined cycle so that the shutoff valve is not closed due to a hypersensitivity reaction caused by a shock other than an earthquake. As a result, the microcomputer does not usually judge an earthquake as a vibration such as an impact that is not caused by an earthquake.

[0006]

However, the above-mentioned conventional method cannot estimate the magnitude of damage caused by an earthquake,
Therefore, the gas meter shuts off the gas uniformly, and the treatment cannot be selected depending on the magnitude of the earthquake. Therefore, it is necessary to take more sufficient earthquake countermeasures in the following points.

The detection output of the seismic detector is a digital value indicating whether there is a seismic intensity of 5 or more, and the microcomputer cannot recognize whether the seismic intensity is 6 or 7 or a seismic intensity greater than 7. . Therefore, it is necessary to shut off the shutoff valve on the safer side, and it is not possible to finely control the shutoff valve according to the seismic intensity. For example, even if an earthquake with a seismic intensity of 5 or more occurs, there is a case where the shutoff valve may be restored without damaging the pipe. Also, in the case of a very strong earthquake, it may be the safe side to prevent the shutoff valve from being restored by any means.

Therefore, an object of the present invention is to estimate the damage caused by an earthquake without judging the seismic intensity of the earthquake, and perform the processing of shutting off and returning the shutoff valve more accurately according to the estimated degree of damage. It is to provide a signal processing method of a gas meter and a seismic sensor capable of achieving the above.

[0009]

According to the first aspect of the present invention, the above object is to provide a seismic detector for detecting an earthquake having a magnitude greater than or equal to a predetermined seismic intensity, and a gas pipe by the output of the seismic detector. In a gas meter having at least a control means for shutting off a shutoff valve provided therein, the control means measures an occurrence time interval of consecutive earthquakes, and after the shutoff valve is shut off by the control means. When the measured occurrence time interval is longer than a first time, the shutoff valve is reset to a first mode, and when the measured time interval is less than the first time, a shutoff valve is reset to a second mode. This is achieved by providing a gas meter characterized by the above.

Further, according to the second invention, the above object is
In the first aspect of the invention, the control means, in the case of the first mode, before detecting the shutoff valve, when the occurrence time interval detects a new earthquake of the first time or less, This is accomplished by providing a gas meter that is bimodal.

Further, according to the third invention, the above object is
In a gas meter having at least a seismoscope for detecting an earthquake having a magnitude of a predetermined seismic intensity or more, and a control means for shutting off a shutoff valve provided in the gas pipe by the output of the seismic shock absorber, the control means is continuous. The occurrence time interval of the earthquake that occurs by, after the shut-off valve is shut off by the control means, when the occurrence time interval is longer than a first time to the first mode to restore the shut-off valve, When the time is longer than the second time and is shorter than the first time and is shorter than or equal to the first time, the second mode that allows the manual return of the shut-off valve is permitted, and when the time is equal to or shorter than the second time, the shut-off valve is returned. It is achieved by a gas meter characterized by setting a third mode for prohibiting.

Further, according to the fourth invention, the above object is to provide:
In the third aspect of the invention, the control means, in the case of the first mode, before the return of the shutoff valve, when detecting a new earthquake of the occurrence time interval is less than or equal to a first time, It becomes the second mode or the third mode, and in the case of the second mode, when a new earthquake whose occurrence time interval is the second time or less is detected before the shutoff valve returns, it becomes the third mode. This is achieved by providing a gas meter characterized by the above.

Further, according to the fifth invention, the above object is to provide:
In a gas meter having at least a seismoscope for detecting an earthquake having a magnitude equal to or higher than a predetermined seismic intensity, and a control means for shutting off a shutoff valve provided in the gas pipe by the output of the seismic shock absorber, the control means is a predetermined When the number of occurrences of an earthquake having a magnitude greater than or equal to the predetermined seismic intensity that occurs within a time period is counted and the shutoff valve is shut off by the control means, the counted number of occurrences is equal to or less than a first number of occurrences The present invention is achieved by providing a gas meter characterized by setting a first mode in which a shutoff valve is returned to a first mode, and setting a second mode in which the shutoff valve is prohibited from returning when the number of occurrences is greater than the first number of occurrences.

Further, according to the sixth invention, the above object is to provide:
In the fifth aspect of the invention, the control means, in the case of the first mode, when detecting a new earthquake having a number of occurrences greater than a first number of times before returning the shutoff valve, This is achieved by providing a gas meter which is characterized by being in mode.

Further, according to the seventh invention, the above object is to provide:
In a gas meter having at least a seismoscope for detecting an earthquake having a magnitude equal to or higher than a predetermined seismic intensity, and a control means for shutting off a shutoff valve provided in the gas pipe by the output of the seismic shock absorber, the control means is a predetermined When the number of occurrences of an earthquake having a magnitude greater than or equal to the predetermined seismic intensity that occurs within a time period is counted, and the shutoff valve is shut off by the control means, the shutoff valve is generated when the number of occurrences is less than or equal to a first occurrence number. To a first mode for returning, and when it is less than or equal to a second number of occurrences that is greater than the first number of occurrences and is greater than the first number of occurrences, a second mode that permits manual return of the shutoff valve, This is achieved by providing a gas meter characterized by setting a third mode in which the return of the shutoff valve is prohibited when the number of occurrences is greater than the second number of occurrences.

Further, according to the eighth invention, the above object is to:
In the seventh invention, the control means, in the case of the first mode, when detecting a new earthquake with the number of occurrences greater than the first number of times before the shutoff valve returns, Mode or third mode, and in the case of the second mode, when a new earthquake with the number of occurrences greater than the second number is detected before the shutoff valve returns, the third mode is entered. This is accomplished by providing a featured gas meter.

Further, according to the ninth invention, the above object is to:
In the first, third, fifth and seventh inventions, the control means performs a self-diagnosis including at least a gas pipe leak diagnosis when the return of the shutoff valve is permitted, and when an abnormality is detected. This is achieved by providing a gas meter characterized by prohibiting the return of the shutoff valve.

Further, according to the tenth aspect of the present invention, in the first, third, fifth and seventh aspects, in the second mode, an alarm is transmitted to a remote center. Is achieved by providing.

[0019]

BEST MODE FOR CARRYING OUT THE INVENTION Embodiments of the present invention will be described below with reference to the drawings. However, the technical scope of the present invention is not limited to this embodiment.

FIG. 1 is a block diagram schematically showing the structure of a gas meter according to this embodiment. The seismoscope 20 according to the present embodiment outputs a digital signal 21 such as ON when the vibration is equal to or more than a predetermined vibration and OFF when the vibration is less than the predetermined vibration.

Reference numeral 30 is a microcomputer corresponding to the control means, and its internal structure is that of a general microcomputer. CPU 31, RAM 32, ROM
33 is connected via the bus 34. The I / O unit 35 is also connected as an interface. When an earthquake exceeding the above-mentioned predetermined conditions is detected, the gas cutoff signal 22 is sent from the microcomputer 30 to the gas pipe 5
The gas cutoff valve 40 is sent to the gas cutoff valve 40 provided inside the valve 0, and the gas cutoff valve 40 is shut off.

As described above, the seismograph 20 reacts only when an earthquake with an intensity of 5 or more occurs, but it is not possible to determine whether the intensity is 5, 6, or 7 or more. However, even if the seismic intensity of the earthquake cannot be determined, the degree of damage caused by the earthquake can be determined by the following method. That is, an earthquake usually occurs once, and then again after a certain time. Also, it may be repeated more than once. When the magnitude of the earthquake is as large as the seismic intensity of 5 or more, it is estimated that the shorter the interval between the earthquakes, the greater the damage of the earthquake.

Therefore, in the embodiment of the present invention, once an earthquake with an intensity of 5 or more is detected and the gas shutoff valve is shut off as before, when an earthquake with an intensity of 5 or more occurs again within a predetermined time, By measuring the interval of occurrence time, the damage of the earthquake is estimated, and it becomes possible to select the shutoff valve shutoff or restoration process.

2 and 3 are flowcharts of a control program in the microcomputer 30 for carrying out the above method.

First, in steps S1 and S2, when an earthquake with a seismic intensity of 5 or more is sensed, the microcomputer 30 immediately issues a shutoff signal to the shutoff valve 40 to shut off the shutoff valve. (Step S3). If the seismic intensity is 4 or less, the shutoff valve will not be closed.

After that, the timer is started (step S4), and the interval between re-occurring earthquakes is measured for a predetermined time. When an occurrence of an earthquake with a seismic intensity of 5 or more is detected during measurement by the timer (steps S6 and S7), in the present embodiment, one of three processing methods predetermined according to the occurrence time interval is selected. One is selected in step S8. This is because, as described above, it is estimated that the damage of the earthquake will also be different if the occurrence time intervals are different, so that the processing is performed according to the degree of the damage.

The above three processing methods are divided into two threshold values of the occurrence time interval t, the first time t1 and the second time t2 from the longest one. That is, if the occurrence time interval t is longer than t1, step S9; if the occurrence time interval t is longer than t2 but is t1 or less, step S9.
10. If the occurrence time interval t is t2 or less, step S1
1 is selected respectively.

Since the occurrence time interval is relatively long in step S9, it is estimated that the degree of damage of the earthquake is not so great, and after a leak inspection as described later, if there is no abnormality, automatic recovery is performed. Of course, it is also possible to manually return as in the conventional case.

Since it is estimated that the damage is greater in step S10 than in step S9, automatic restoration is not permitted and only manual restoration is permitted. This is because unpredictable injuries may occur and it is necessary to artificially check for injuries that cannot be detected by the leak test performed by the microcomputer.

In step S11, since it is estimated that the damage caused by the earthquake is even greater, there is a high possibility that the piping system will be injured, and for any reason, the inspection above a certain level is not performed. The return of the shut-off valve is not permitted, and the alarm is sent to the center via the communication line.

Further, when the earthquake having the seismic intensity of 5 or more does not occur again within the predetermined time, the step S9 selected when the damage is estimated to be the smallest among the three processing methods is selected. .

In step S8, step S9 (t>
When t1) is selected, the once cleared timer (step S9) is restarted (step 1
2) After that, for example, the self-diagnosis program in the microcomputer 30 starts a leak check for leaks in the indoor piping system downstream from the gas meter (step S15). The reason why the timer measurement is performed during the leak inspection is that an earthquake may occur again during the leak inspection, and an appropriate processing method can be selected again depending on the time interval at which the earthquake occurs. For example, if
When an earthquake with a seismic intensity of 5 or more is detected during the leak inspection (steps S16 and S17), the process returns to step S8 again, and the processing method determined by the occurrence time interval t is selected.

The leak inspection is completed (step S18), and it is determined whether there is any leak (step S20). If it is determined that there is no leak, the shutoff valve 40 is automatically returned (step S21). A return signal is issued from the microcomputer 30 and the shutoff valve is opened. If it is determined that there is leakage, the shutoff valve is prohibited from returning (step S2
0) Make sure that the shut-off valve is not allowed to return unless it is inspected at a certain level or higher.

If step S10 (t2 <t≤t1) is selected, automatic restoration is not permitted, and only manual restoration is permitted, so it is only issued after a human on-site check is performed. Until there is a manual return signal (step S25), the leak check and the shutoff valve return are not performed. Similarly to the above, once the timer is cleared in step S10, the timer measurement starts again (step S13), and it is determined whether or not there is an earthquake with a seismic intensity of 5 or more until the manual return signal is received (steps S23 and S).
24) When such an earthquake occurs, an appropriate processing method is selected again as described above (step S3).
0). Note that since step S10 is once selected, even if the subsequent occurrence time interval t is the time corresponding to step S9, step S9 is taken for safety management.
It is to not proceed to. Therefore, in step S30, it is determined whether the occurrence time interval t is the second time t2 or less. Thereby, the shortest occurrence time interval is used.

When the microcomputer receives the manual return signal (step S25), it starts the leak inspection (step S26). During the leak inspection as well as above, the presence or absence of an earthquake with a seismic intensity of 5 or more (step S27 and step S28) and the occurrence time interval t are measured in order to select an appropriate processing method when an earthquake with an abnormal seismic intensity of 5 occurs. (Step S3
0). If there is no leak, a return signal is issued from the microcomputer 30 and the shutoff valve is opened (step S21). If it is determined that there is a leak, the shut-off valve is prohibited from being restored (step S20), and the shut-off valve is not permitted to be restored unless an inspection at a certain level or higher is performed.

When step S11 (t≤t2) is selected at the end, an earthquake has occurred at an extremely short time interval and there is a high possibility that the piping system is injured, so both automatic recovery and manual recovery are possible. It is banned and an alarm is sent to the center.

As described above, after the interruption by the first earthquake, the time until the next earthquake is measured, and the time is divided into three levels (modes) of steps S9, S10 and S11 according to the occurrence time interval. , If an earthquake is detected at a shorter time interval, a more severe step (mode)
I will move to S10, 11. By doing so, it is possible to always select the processing method that stands on the safest side.

4 and 5 are flow charts of a control program for a shutoff valve according to another embodiment of the present invention.

In this embodiment, the occurrence time interval t measured in the above-mentioned embodiment is not measured, but instead,
The number of occurrences n of earthquakes having an intensity of 5 or more within a predetermined time is counted, and the three processing methods are selected according to the number of occurrences n. This is because the damage of an earthquake can be estimated from the number of times of occurrence of a large earthquake with a seismic intensity of 5 or more, and it is considered that the greater the number of occurrences, the greater the damage due to the earthquake.

Similar to the above-described embodiment, first, in steps S1 and S2, when an earthquake with a seismic intensity of 5 or more is detected, the shutoff valve is shut off (step S3). After that, the timer is started (step S4), and the number of times of re-occurring earthquake is counted for a predetermined time (step S7). There are two thresholds for the number of occurrences n, the first occurrence number n1 and the second occurrence number n from the smallest value.
2 are provided, which separate the three treatment methods. When a predetermined time has passed (step S7)
1) In step S8, one of the three processing methods is selected according to the number of occurrences n. If the number of occurrences n is n1 or less, it is determined that the damage of the earthquake is relatively small, and step S9 is selected. Furthermore, if the number of occurrences n is greater than n1 but less than or equal to n2, step S1
If 0 and the number of occurrences n is greater than n2, the strictest step S11 is selected. Here, steps S9, 10 and 11 in the flow chart of the present embodiment correspond to steps S9, 10 and 11 of the above-described embodiment, respectively, and therefore description thereof will be omitted.

After each processing method is selected, the process is almost the same as that of the above-described embodiment. That is, instead of the occurrence time interval t of the seismic intensity of 5 or more measured in the above-described embodiment, the number of occurrences n of the seismic intensity of 5 or more within a predetermined time is counted (steps S16, 23, 27),
If the number of occurrences is larger than before, the process of selecting again an appropriate processing method according to the damage of the earthquake is performed (step S8,
30). Then, in step S9, the microcomputer checks for leaks by the self-diagnosis program (steps S18 and S26). If there is no leak, the shutoff valve is restored. If leak is found, the shutoff valve is restored. Ban. (Steps S19, 20, 21). Step S10
In the same, after the microcomputer receives the manual return signal, the same leak test is performed (step S26), and it is determined whether or not the shutoff valve is reset depending on the presence or absence of the leak (steps S19, 20, 21). . Finally, step S
In 11, neither automatic nor manual restoration is prohibited, and an alarm is sent to the center.

[0042]

As described above, according to the present invention, the damage due to an earthquake can be estimated without detecting the magnitude of the earthquake by measuring the time interval or the number of times of occurrence of the earthquake having a seismic intensity of a predetermined value or more. , The optimum control of the shutoff valve can be performed according to the degree of the damage.

[Brief description of drawings]

FIG. 1 is a schematic block diagram of a gas meter according to an embodiment of the present invention.

FIG. 2 is a flowchart (part 1) of a control program for a shutoff valve according to the embodiment of the present invention.

FIG. 3 is a flowchart (part 2) of the control program for the shutoff valve according to the embodiment of the present invention.

FIG. 4 is a flowchart (part 1) of a control program for a shutoff valve according to another embodiment of the present invention.

FIG. 5 is a flowchart (part 2) of a shutoff valve control program according to another embodiment of the present invention.

[Explanation of symbols]

20 seismic devices 30 microcomputer 40 shut-off valve

─────────────────────────────────────────────────── ─── Continuation of the front page (56) Reference JP-A-8-5448 (JP, A) JP-A-7-239099 (JP, A) JP-A-57-148123 (JP, A) (58) Field (Int.Cl. ⁷ , DB name) F23N 5/24 111 F23N 5/24 101

Claims (10)

(57) [Claims] 1. A gas meter having at least a seismoscope for detecting an earthquake having a magnitude greater than or equal to a predetermined seismic intensity, and a control means for shutting off a shutoff valve provided in a gas pipe by the output of the seismoscope, The control means measures the occurrence time intervals of consecutive earthquakes, and when the measured occurrence time interval is longer than a first time after the shutoff valve is shut off by the control means, the shutoff valve is The gas meter is set to a first mode for resetting the shutoff valve, and a second mode for prohibiting the shutoff valve from being reset when the time is less than the first time. 2. The gas meter according to claim 1, wherein the control means detects a new earthquake in which the generation time interval is the first time or less before the shutoff valve returns in the first mode. At the time, the second mode is set. 3. A gas meter having at least a seismoscope for detecting an earthquake having a magnitude greater than or equal to a predetermined seismic intensity, and a control means for shutting off a shut-off valve provided in the gas pipe by the output of the seismoscope, The control means measures the time intervals of occurrence of consecutive earthquakes and, after the shut-off valve is shut off by the control means, restores the shut-off valve when the time interval is longer than a first time. In the first mode, when the second time shorter than the first time and longer than the first time is less than or equal to the first mode, the second mode that permits the manual return of the shutoff valve is allowed, and when the second time is less than or equal to A gas meter, which is set to a third mode for prohibiting the return of the shutoff valve. 4. The gas meter according to claim 3, wherein the control means detects a new earthquake in which the generation time interval is the first time or less before the shutoff valve returns in the first mode. Time is the second mode or the third mode, in the case of the second mode, before the return of the shutoff valve, when the occurrence time interval detects a new earthquake of the second time or less, It is characterized by becoming the third mode. 5. A gas meter having at least a seismoscope for detecting an earthquake having a magnitude greater than or equal to a predetermined seismic intensity, and a control means for shutting off a shutoff valve provided in a gas pipe by the output of the seismic shock absorber. The control means counts the number of occurrences of an earthquake having a magnitude equal to or greater than the predetermined seismic intensity that occurs within a predetermined time, and after the shutoff valve is shut off by the control means, the counted number of occurrences is the first occurrence number. The gas meter is set to a first mode in which the shut-off valve is returned in the following cases, and in a second mode in which the shut-off valve is prohibited to return when the number of occurrences is greater than the first number of occurrences. 6. The gas meter according to claim 5, wherein the control means detects a new earthquake in which the number of occurrences is greater than the first number of times in the first mode and before the shutoff valve is returned. Is in the second mode. 7. A gas meter comprising at least a seismoscope for detecting an earthquake having a magnitude greater than or equal to a predetermined seismic intensity, and a control means for shutting off a shutoff valve provided in the gas pipe by the output of the seismic shock absorber. The control means counts the number of times of occurrence of an earthquake having a magnitude greater than or equal to the predetermined seismic intensity that occurs within a predetermined time, and after the shutoff valve is shut off by the control means, the number of occurrences is equal to or less than a first occurrence number. When the shutoff valve is returned to the first mode, the shutoff valve is allowed to be manually returned when the shutoff valve is greater than the first occurrence count and equal to or less than the second occurrence count and greater than the first occurrence count. A gas meter, wherein the gas meter is set to the second mode, and when it is more than the second number of occurrences, the third mode is set to prohibit the return of the shutoff valve. 8. The gas meter according to claim 7, wherein the control means detects a new earthquake in which the number of occurrences is greater than the first number of times before the return of the shutoff valve in the first mode. Is the second mode or the third mode, and in the case of the second mode, when a new earthquake with the number of occurrences greater than the second number is detected before the shutoff valve returns, the third It is characterized by becoming a mode. 9. The gas meter according to claim 1, 3, 5, or 7, wherein the control means performs a self-diagnosis including at least a gas pipe leak diagnosis when the return of the shutoff valve is permitted, It is characterized by prohibiting the return of the shutoff valve when an abnormality is detected. 10. The gas meter according to any one of claims 1, 3, 5 and 7, wherein in the second mode or the third mode, a corresponding alarm is transmitted to a remote center.