JP4482351B2 - Return safety confirmation method and electronic gas meter - Google Patents

Description

  The present invention relates to a return safety confirmation method for confirming safety when a gas supply is restored after the gas supply is shut off due to a gas supply abnormality or the like, and an electronic gas meter that implements the method.

  In recent years, electronic gas meters have a function of measuring the flow rate of gas flowing in a gas flow path, and the flow rate exceeds a predetermined total flow rate value (preset by summing the consumption flow rate of connected combustors). If the combustor is used continuously for a predetermined period or longer, an abnormality such as gas leakage in the gas flow path or forgetting to turn off the combustor is detected, and the gas shut-off valve is closed to The number of devices having a safety shut-off function that shuts off the gas supply through the flow path is increasing.

  In addition to the safety shut-off function at the time of abnormality, there is also a test shut-off function that shuts off the gas supply through the gas flow path by closing the gas shut-off valve for testing in order to check the operation status of the gas meter. .

  Therefore, when opening and returning a gas shut-off valve that has been closed by a safety shut-off function or a test shut-off function, the gas shut-off valve is opened only when it is safe, while checking safety for gas leaks. Need to be restored. Therefore, the gas meter is equipped with a function of checking the presence or absence of leakage for a predetermined time (recovery safety confirmation time) after being shut off by these shut-off functions, and setting it to a normal use state if there is no leak. This function is called a return safety confirmation function.

A technique for providing a predetermined return safety confirmation time when returning after shut-off by the shut-off function is disclosed in, for example, Japanese Patent Application Laid-Open No. 2001-33289. In this technique, the return safety confirmation time at the time of return is fixed to a constant value (for example, 1 minute). If the gas flow rate does not change by a predetermined time before shut-off, the gas meter is put into a normal use state without waiting for the return safety check time when returning at shut-off, that is, without performing the return safety check work. It was.
JP 2001-33289 A

  In the above-mentioned technology, based on the presence or absence of the gas flow before shutoff, after the shutoff valve is automatically restored, the gas meter is immediately put into a normal use state without performing the return safety check work, or the return safety check work is performed. After that, the gas meter is in normal use.

  However, in the above-described technique, there is a case where the return safety confirmation work is not performed at the time of shutoff, and it cannot be said that the gas meter is safe for safe use. Therefore, it can be said that the return safety confirmation work must be performed at the time of interruption.

  However, when the shut-off function is used, the return safety check time is not necessarily set to a constant return safety check time. Although it may be good, in the conventional gas meter, as described above, the return safety confirmation time at the time of return is fixed to a constant value, so the end of the return safety check work will be waited until the time elapses. There is a problem that work efficiency deteriorates at the time of construction of the gas meter.

  Therefore, in view of the above-described conventional problems, an object of the present invention is to provide a return safety confirmation method and an electronic gas meter capable of performing a return safety check earlier and safely.

  The return safety confirmation method according to the first aspect of the present invention provides a gas supply by opening the shut-off valve based on an input of a return signal after occurrence of a shut-off event in which the gas meter shut-off valve is closed and the gas supply is shut off. A return safety confirmation method for confirming return safety when returning the vehicle, wherein the flow rate immediately before the shutoff is monitored, and if there is no flow rate, the return safety check time is set to a first predetermined value and When there is a flow rate, the return safety confirmation time is set to a second predetermined value that is longer than the first predetermined value, and whether or not there is a leakage flow rate during the return safety confirmation time of the first or second predetermined value Based on the above, the return safety is confirmed.

  According to a second aspect of the present invention, in the return safety confirmation method according to the first aspect, when the leakage flow rate is present during the return safety confirmation time of the first or second predetermined value, the shut-off valve is set. The valve is closed to shut off the gas supply, and when there is no leakage flow rate, the shutoff valve is kept open and the return safety check is completed.

  According to a third aspect of the present invention, there is provided an electronic gas meter comprising: a shut-off unit comprising a shut-off valve that shuts off a gas flow path; and a shut-off event in which gas supply is shut off by the shut-off valve, based on an input of a return signal. An electronic gas meter comprising a return safety check means for checking return safety when the valve is opened to return the gas supply, further comprising a flow rate presence / absence monitoring means for monitoring the flow rate immediately before the shutoff The return safety confirmation means sets the return safety confirmation time to a first predetermined value when there is no flow based on the monitoring by the flow rate presence / absence monitoring means, and sets the return safety confirmation time when there is the flow. The second predetermined value longer than the first predetermined value is set, and the return safety is confirmed based on the presence or absence of a leakage flow rate during the return safety confirmation time of the first or second predetermined value. To do.

  According to a fourth aspect of the present invention, in the electronic gas meter according to the third aspect, the return safety confirmation means has the leakage flow rate during the return safety confirmation time of the first or second predetermined value. In this case, the shutoff valve is closed to shut off the gas supply, and when there is no leakage flow rate, the shutoff valve is kept open and the return safety check is completed.

  According to a fifth aspect of the present invention, in the electronic gas meter according to the third or fourth aspect, the return safety confirmation means includes a flow rate monitoring unit that monitors an instantaneous flow rate of the gas flowing through the gas flow path, and the flow rate monitoring unit. A data calculation unit that calculates an instantaneous flow rate value by performing calculation based on the supplied detection output, a data storage unit that stores the instantaneous flow rate value calculated by the data calculation unit, A threshold value storage unit for storing a preset flow rate threshold value; the instantaneous flow rate value stored in the data storage unit; and the flow rate threshold value stored in the threshold value storage unit; Based on the monitoring of the flow rate presence / absence monitoring means and the flow rate presence / absence monitoring means, the return safety confirmation time is set to a first predetermined value when there is no flow rate and the flow rate is present. Before The return safety confirmation time is set to a second predetermined value longer than the first predetermined value, and the comparison result from the data comparison unit during the return safety confirmation time of the first or second predetermined value is as follows: When the instantaneous flow rate value is larger than the flow rate threshold value, the shutoff valve is closed to shut off the gas supply, and when the flow rate is less than the flow rate threshold value, the shutoff valve valve And a control unit that maintains the open state and ends the return safety confirmation.

  According to the first and third aspects of the invention, the return safety confirmation time is set to a different predetermined value depending on the situation (particularly, depending on the presence or absence of the flow rate immediately before the shut-off), thereby further improving the return safety confirmation work. It can be carried out quickly and safely, and the work efficiency at the time of construction by the gas company can be improved.

  According to the second, fourth, and fifth aspects of the present invention, if there is a leakage flow rate during the return safety confirmation time, it is shut off again, and if there is no leakage flow rate, the return safety confirmation ends, so safety is improved.

DESCRIPTION OF THE PREFERRED EMBODIMENTS Embodiments of an electronic gas meter for carrying out a return safety confirmation method according to the present invention and a reference example useful for understanding the gist of the present invention will be described below with reference to the drawings.

(Embodiment)
The gas meter is equipped with a security function that allows the use of the gas meter after confirming that there is no problem by checking the presence or absence of gas leakage, instead of returning it as it is when a shut-off event occurs. This is called a return safety confirmation function. There are two types of return safety confirmation parameters. One is when there is no combustion device with a minimum flow rate, and the other is when there is a combustion device with a minimum flow rate. The presence / absence setting of the minimum flow combustion appliance is set by the gas company according to the situation of the house.

  The minimum flow rate combustion appliance is a combustion appliance whose gas flow rate corresponds to the minimum flow rate classification (flow rate of 21 L / h or less) among the flow rate categories of the combustion appliance in the usage time cutoff function, such as a gas table in a general household. There is. The use time shut-off function is a function that shuts off gas when it is determined that the burner has been used for an abnormally long time, for example, gas leakage due to forgetting to turn off the burner or incomplete closure of the tool plug. When there is a setting of the minimum flow rate combustion appliance (that is, when there is a minimum flow rate combustion appliance), the usage time is cut off at a minimum flow rate in the range of 8.3 L / h to 21 L / h.

  The return safety confirmation completion time for the S-type gas meter is 60 seconds when there is no setting of the minimum flow rate combustion appliance, and 150 seconds when there is a setting of the minimum flow rate combustion appliance. Also, it is necessary to wait for the completion of the return safety check, and particularly when it is set to have a combustion apparatus with a minimum flow rate, the waiting time becomes long and the work efficiency becomes poor.

  In the first place, the return safety confirmation function is provided when there is a risk of release of raw gas when a shutoff event occurs and the gas plug of the combustion appliance used before shutoff is open at the time of return. Function. In other words, it is necessary to confirm the presence or absence of gas leakage during the 150 second waiting time for the shut-off in the gas use state, but in the case of other shut-off, it is necessary to request accuracy up to that point. Absent.

Therefore, in the embodiment of the present invention, a return safety confirmation method that can shorten the return safety confirmation time, which has conventionally been one-sided, according to the situation by having the flow presence / absence immediately before the shutoff as information, and an electronic method for implementing the method A gas meter is proposed.

FIG. 1 is a block diagram showing an electronic gas meter that implements a return safety confirmation method according to an embodiment of the present invention. In FIG. 1, an electronic gas meter includes a flow rate monitoring unit 1, a data calculation unit 2, a data storage unit 3, a threshold value storage unit 4, a data comparison unit 5, a return signal input unit 6, a flow rate presence / absence monitoring unit 7, and a control unit. 8 and a blocking unit 9.

  The flow rate presence / absence monitoring unit 7 functions as flow rate presence / absence monitoring means in the claims. The flow rate monitoring unit 1, the data calculation unit 2, the data storage unit 3, the threshold value storage unit 4, the data comparison unit 5, and the control unit 8 function as return safety confirmation means in the claims.

  The flow rate monitoring unit 1 monitors the flow rate of the gas flowing through the gas flow path, and includes a flow rate sensor such as an ultrasonic sensor or a flow sensor that can detect an instantaneous flow rate. The data calculation unit 2 is supplied with a flow rate detection output from the flow rate monitoring unit 1 by flow rate sampling at a predetermined value interval, and calculates based on the supplied flow rate detection output to calculate an instantaneous flow rate.

  The data storage unit 3 stores the instantaneous flow rate calculated by the data calculation unit 2. The threshold value storage unit 4 stores a preset flow rate threshold value.

  The flow rate threshold value is a threshold value for determining whether or not the leakage flow rate is flowing, and is set to, for example, 8.3 liters / hour (L / h).

  The data comparison unit 5 compares the instantaneous flow rate stored in the data storage unit 3 with the flow rate threshold value stored in the threshold value storage unit 4 and outputs the comparison result.

  The return signal input unit 6 includes a shut-off valve opening switch (not shown) that is turned on when a return button (not shown) is pressed. The flow rate presence / absence monitoring unit 7 monitors the presence / absence of the flow rate immediately before the shut-off, specifically, “0” indicating that the flow is interrupted when there is no flow rate, and “ 1 "is stored.

  The control unit 8 outputs an instruction signal that instructs the flow rate monitoring unit 1 to perform flow rate sampling at predetermined value intervals. Further, the control unit 8 controls the shut-off unit 9 so that the shut-off valve is closed, or the shut-off valve is opened according to the input of the comparison result from the data comparison unit 5. The shut-off valve return signal to be controlled is output. The shut-off unit 9 includes a shut-off valve that is controlled by a shut-off valve return signal or a shut-off valve close signal from the control unit 8 to open and close the gas flow path.

  The data calculation unit 2, the data storage unit 3, the threshold value storage unit 4, the data comparison unit 5, the flow rate presence / absence monitoring unit 7 and the control unit 8 can be configured by a microcomputer having a CPU, a ROM, and a RAM. In this case, the CPU functions as the data calculation unit 2, the data comparison unit 5, and the control unit 8, the ROM functions as the threshold value storage unit 4, and the RAM functions as the data storage unit 3 and the flow rate presence / absence monitoring unit 7.

  In the above-described configuration, when the control unit 8 receives a shut-off instruction, the control unit 8 stores information (whether or not there is a flow rate) at that time in the flow rate presence or absence monitoring unit 7. The stored information (flow rate presence / absence) is secured until a return signal is input from the return signal input unit 6. Upon receiving the return signal from the return signal input unit 6, the control unit 8 sets a return safety confirmation time based on the flow rate presence / absence information of the flow rate presence / absence monitoring unit 7 and simultaneously sends a shut-off valve return signal to the cutoff unit 9. Output and shift to return safety check mode. After completion of the return signal output, the control unit 8 instructs the instantaneous flow rate monitoring unit 1 to perform flow rate sampling. Each sampling result is calculated by the data calculation unit 2, and the calculated instantaneous flow rate value is stored in the data storage unit 3. When the instantaneous flow rate is equal to or less than the instantaneous flow rate threshold value stored in the threshold value storage unit 4 within the set return safety confirmation time, the data comparison unit 5 has no problem with respect to completion of return safety. And outputs a signal to the control unit 8. In response to the signal, the control unit 8 ends the return safety confirmation.

  Next, the operation of the above-described electronic gas meter will be described with reference to the flowcharts shown in FIGS.

  FIG. 2 is a flowchart showing the flow rate presence / absence recording process. First, the control unit 8 determines whether or not there is a blocking event (step S1). This determination is to determine that there is a shut-off event when a shut-off valve closing signal is output from the control unit 8 to the shut-off unit 9. Next, the flow rate presence / absence determination flag state is stored in the flow rate presence / absence monitoring unit 7. This flow rate presence / absence determination flag is “0” indicating that the flow is interrupted when there is no flow rate, or “1” that indicates that the flow is interrupted when there is a flow rate.

  Therefore, if a shut-off event occurs when a combustion device with a minimum flow rate is in use, the flow rate judgment flag is set when the flow rate is low. “1” indicating that the value is stored in the flow rate presence / absence monitoring unit 7. In addition, if a shut-off event occurs when the combustor with the minimum flow rate is not in use, it will be shut off when the gas with the minimum flow rate is not flowing through the gas flow path. “0” representing that is stored in the flow rate presence / absence monitoring unit 7.

  FIG. 3 is a flowchart showing the processing operation of the return safety confirmation function.

  First, after a shut-off by any shut-off function, the shut-off valve opening switch is turned on by pressing the return button, whereby the return signal from the return signal input unit 6 is input to the control unit 8 (step S11).

  Next, the control unit 8 outputs a shut-off valve return signal based on the input of the return signal (step S12). Thereby, the cutoff part 9 is controlled by the cutoff valve return signal from the control part 8, and the cutoff valve is opened.

  Next, the control unit 8 determines whether or not the state of the flow rate presence / absence determination flag stored in the flow rate presence / absence monitoring unit 7 is “1” (step S13).

  If the flow rate presence / absence determination flag is not “1” (No in step S13), the control unit 8 then sets the return safety confirmation parameter type 1 (step S14). The return safety confirmation parameter type 1 corresponds to a case where there is no combustion device with a minimum flow rate. By setting the return safety confirmation parameter type 1, the return safety confirmation time as the return safety confirmation parameter is set to a first predetermined value (for example, 60 seconds), and the return safety confirmation completion timer counts this first predetermined value. Starts.

  On the other hand, if the flow rate presence / absence determination flag is “1” (Yes in step S13), the control unit 8 then sets the return safety confirmation parameter type 2 (step S15). The return safety confirmation parameter type 2 corresponds to the case where there is a combustion apparatus with a minimum flow rate. By setting the return safety confirmation parameter type 2, the return safety confirmation time as the return safety confirmation confirmation parameter is set to a second predetermined value (for example, 150 seconds) longer than the first predetermined value, and this second predetermined value is set. The return safety confirmation completion timer starts counting.

  Next, the control unit 8 instructs the flow rate monitoring unit 1 to sample the instantaneous flow rate (step S16). Thereby, a flow rate detection signal is output from the flow rate monitoring unit 1, calculated by the data calculation unit 2, and the calculated instantaneous flow rate value Pn is stored in the data storage unit 3.

  Next, the data comparison unit 5 determines whether or not the instantaneous flow rate Pn stored in the data storage unit 3 is larger than the flow rate threshold value (Pn> flow rate threshold value) (step S17). If the answer is No, it will progress to step S18, and if it is Yes, it will progress to step S19.

  In step S18, the control unit 8 determines whether or not the count of the return safety confirmation completion timer exceeds the return safety confirmation time. This determination is made based on the first predetermined value (for example, 60 seconds) set in step S14 or the second predetermined value (for example, 150 seconds) set in step S15.

  If the answer to step S18 is No, the process returns to step S16. If yes, a return safety confirmation signal is output as a return safety confirmation end (step S20), and then the process ends.

  On the other hand, if the answer to step S17 is Yes, the control unit 8 then outputs a shut-off valve closing signal, controls the shut-off valve in the shut-off unit 9 to close, and closes the gas flow path (step S19). ), And then the process ends.

As described above, according to the embodiment of the present invention, the return safety confirmation time is set to a different predetermined value according to the situation (particularly, depending on the presence or absence of the flow rate immediately before the shutoff), so that the return safety confirmation work is performed. Can be carried out earlier and safely, and the work efficiency during construction by the gas company can be improved. Further, if there is a leakage flow rate during the return safety confirmation time, it is shut off again, and if there is no leakage flow rate, the return safety check is completed, so the safety is improved.

(First reference example)
The gas meter is equipped with a security function that allows the use of the gas meter after confirming that there is no problem by checking the presence or absence of gas leakage, instead of returning it as it is when a shut-off event occurs. This is called a return safety confirmation function. There are two types of return safety confirmation parameters. One is when there is no combustion device with a minimum flow rate, and the other is when there is a combustion device with a minimum flow rate. The presence / absence setting of the minimum flow combustion appliance is set by the gas company according to the situation of the house. In the S-type gas meter, the return safety confirmation completion time is 60 seconds for the former and 150 seconds for the latter, but at present, the return safety confirmation must be completed even when the gas company performs construction work. It is necessary to wait, especially when it is set to have a combustion device with a very small flow rate, the waiting time becomes long and the work efficiency deteriorates.

  In the first place, the return safety confirmation function is provided when there is a risk of release of raw gas when a shutoff event occurs and the gas plug of the combustion appliance used before shutoff is open at the time of return. Function. Therefore, the test interruption performed during gas meter construction and inspection is performed only by the gas company and can be limited to the content performed after understanding the on-site situation. Even if it exists, as long as the minimum leakage detection accuracy is ensured, there is no problem as a determination considering work efficiency.

Therefore, in the first reference example useful for understanding the gist of the present invention, the return safety confirmation method and the method that can reduce the return safety confirmation time, which has conventionally been inconvenient, according to the situation by reflecting the blocking information. We propose an electronic gas meter that implements

FIG. 4 is a block diagram showing an electronic gas meter that implements the return safety confirmation method according to the first reference example that is useful for understanding the gist of the present invention . The electronic gas meter includes a flow rate monitoring unit 1, a data calculation unit 2, a data storage unit 3, a threshold value storage unit 4, a data comparison unit 5, a return signal input unit 6, a control unit 8, a cutoff unit 9, and a test signal input unit. 10 and a block information monitoring unit 11.

Blocking information monitoring unit 11 serves as a barrier sectional information monitoring unit. The flow rate monitoring unit 1, the data calculating unit 2, the data storage unit 3, a threshold storage unit 4, the data comparison unit 5 and the control unit 8 acts as a carriage return safety check means.

  The flow rate monitoring unit 1 monitors the flow rate of the gas flowing through the gas flow path, and includes a flow rate sensor such as an ultrasonic sensor or a flow sensor that can detect an instantaneous flow rate. The data calculation unit 2 is supplied with a flow rate detection output from the flow rate monitoring unit 1 by flow rate sampling at a predetermined value interval, and calculates based on the supplied flow rate detection output to calculate an instantaneous flow rate.

  The data storage unit 3 stores the instantaneous flow rate calculated by the data calculation unit 2. The threshold value storage unit 4 stores a preset flow rate threshold value.

  The flow rate threshold value is a threshold value for determining whether or not the leakage flow rate is flowing, and is set to, for example, 8.3 liters / hour (L / h).

  The data comparison unit 5 compares the instantaneous flow rate stored in the data storage unit 3 with the flow rate threshold value stored in the threshold value storage unit 4 and outputs the comparison result.

  The return signal input unit 6 includes a shut-off valve opening switch (not shown) that is turned on when a return button (not shown) is pressed. The test signal input unit 10 includes a test switch (not shown) for performing a test shut-off operation by, for example, manual magnet key (not shown) operation. The blocking information monitoring unit 11 monitors what type of blocking function causes the blocking event, and specifically stores blocking information described later.

  The control unit 8 outputs an instruction signal that instructs the flow rate monitoring unit 1 to perform flow rate sampling at predetermined value intervals. Further, the control unit 8 controls the shut-off valve 9 so as to close the shut-off valve or the shut-off valve controlled to open the shut-off valve in response to the input of the comparison result from the data comparison unit 5. Outputs a valve return signal. The shut-off unit 9 includes a shut-off valve that is controlled by a shut-off valve return signal or a shut-off valve close signal from the control unit 8 to open and close the gas flow path.

  The data calculation unit 2, the data storage unit 3, the threshold value storage unit 4, the data comparison unit 5, the cutoff information monitoring unit 11 and the control unit 8 can be configured by a microcomputer having a CPU, a ROM and a RAM. In this case, the CPU functions as the data operation unit 2, the data comparison unit 5, and the control unit 8, the ROM functions as the threshold value storage unit 4, and the RAM functions as the data storage unit 3 and the cutoff information monitoring unit 11.

  In the above-described configuration, when receiving the blocking instruction, the control unit 8 instructs the blocking information monitoring unit 11 to store the blocking information at that time. The stored cutoff information is secured until a return signal is input from the return signal input unit 6. Upon receiving the return signal from the return signal input unit 6, the control unit 8 sets the return safety confirmation time based on the cutoff information of the cutoff information monitoring unit 11 and simultaneously outputs the cutoff valve return signal to the cutoff unit 9. Then, return to the safety check mode. After completion of the return signal output, the control unit 8 instructs the instantaneous flow rate monitoring unit 1 to perform flow rate sampling. Each sampling result is calculated by the data calculation unit 2, and the calculated instantaneous flow rate value is stored in the data storage unit 3. When the instantaneous flow rate is equal to or less than the instantaneous flow rate threshold value stored in the threshold value storage unit 4 within the set return safety confirmation time, the data comparison unit 5 has no problem with respect to completion of return safety. And outputs a signal to the control unit 8. In response to the signal, the control unit 8 ends the return safety confirmation.

  Next, the operation of the above-described electronic gas meter will be described with reference to the flowcharts shown in FIGS.

  FIG. 5 is a flowchart showing the blocking information recording process. First, the control unit 8 determines whether or not there is a blocking event (step S31). This determination is to determine that there is a shut-off event when a shut-off valve closing signal is output from the control unit 8 to the shut-off unit 9. Next, a cutoff information code for identifying which type of cutoff function has caused the cutoff is stored in the cutoff information monitoring unit 11. For example, the code of the cutoff information is set to “0” for cutoff by the test cutoff function, “1” for cutoff by the total flow cutoff function, and “2” for cutoff by the use time cutoff function. The interruption by the test interruption function is an interruption in a state where no gas is used. Further, the shutoff by the total flow shutoff function or the use time shutoff function is a shutoff in a state where the gas is used.

  FIG. 6 is a flowchart showing the processing operation of the return safety confirmation function.

  First, after a shut-off by any shut-off function, the shut-off valve opening switch is turned on by pressing the return button, whereby the return signal from the return signal input unit 6 is input to the control unit 8 (step S41).

  Next, the control unit 8 outputs a shut-off valve return signal based on the input of the return signal (step S42). Thereby, the cutoff part 9 is controlled by the cutoff valve return signal from the control part 8, and the cutoff valve is opened.

  Next, the control unit 8 determines whether or not the code of the blocking information stored in the blocking information monitoring unit 11 is “0” (step S43). In the case of interruption based on the input of the test signal from the test signal input unit 10 by turning on the test switch (in the case of interruption by the test interruption function), the interruption information monitoring unit 11 stores the interruption information code “0”.

  Therefore, if the shutoff information code is “0” (Yes in step S43), the control unit 8 then sets the return safety confirmation parameter type 1 (step S44). By setting the return safety confirmation parameter type 1, the return safety confirmation time as the return safety confirmation parameter is set to a first predetermined value (for example, 60 seconds), and the return safety confirmation completion timer counts this first predetermined value. Starts.

  On the other hand, when the answer to step S43 is No (that is, when the cutoff information code is “1” or “2”), the control unit 8 then sets the return safety confirmation parameter type 2 (step S45). By setting the return safety confirmation parameter type 2, the return safety confirmation time as the return safety confirmation confirmation parameter is set to a second predetermined value (for example, 150 seconds) longer than the first predetermined value, and this second predetermined value is set. The return safety confirmation completion timer starts counting.

  Next, the control unit 8 instructs the flow rate monitoring unit 1 to sample the instantaneous flow rate (step S46). Thereby, a flow rate detection signal is output from the flow rate monitoring unit 1, calculated by the data calculation unit 2, and the calculated instantaneous flow rate value Pn is stored in the data storage unit 3.

  Next, the data comparison unit 5 determines whether or not the instantaneous flow rate Pn stored in the data storage unit 3 is larger than the flow rate threshold value (Pn> flow rate threshold value) (step S47). If the answer is No, it will progress to step S48, and if it is Yes, it will progress to step S49.

  In step S48, the control unit 8 determines whether or not the count of the return safety confirmation completion timer has exceeded the return safety confirmation time. This determination is made based on a comparison with the first predetermined value (for example, 60 seconds) set at step S44 or the second predetermined value (for example, 150 seconds) set at step S45.

  If the answer to step S48 is no, the process returns to step S46. If yes, a return safety confirmation signal is output as a return safety confirmation end (step S50), and then the process ends.

  On the other hand, if the answer to step S47 is Yes, the control unit 8 then outputs a shut-off valve closing signal, controls the shut-off valve in the shut-off unit 9 to be closed, and closes the gas flow path (step S49). ), And then the process ends.

As described above, according to the first reference example , the return safety confirmation time is set to a different predetermined value depending on the situation (particularly, depending on the type of the interruption event), so that the return safety confirmation work can be performed more quickly. It can be carried out safely and the work efficiency at the time of construction by the gas company can be improved. Further, if there is a leakage flow rate during the return safety confirmation time, it is shut off again, and if there is no leakage flow rate, the return safety check is completed, so the safety is improved.

(Second reference example)
The gas meter is equipped with a security function that allows the use of the gas meter after confirming that there is no problem by checking the presence or absence of gas leakage, instead of returning it as it is when a shut-off event occurs. This is called a return safety confirmation function. Shut-off events occur due to various functions such as total flow rate shut-off, use time shut-off, seismic device shut-off, and shut-off during return safety confirmation.However, safety-related parts are defined in technical standards and Is essential. However, at present, the only item that can be set is the presence or absence of a minimum flow rate combustor. For example, in the case of an S-type gas meter, for a flow rate that does not correspond to the minimum flow rate, a flow rate classification is set for every fixed flow rate interval, and the operating time cutoff works according to each flow rate, and the return safety confirmation time Completion in 1 minute is an essential item. However, only when the minimum flow rate combustion appliance is set, the time until the return safety confirmation determination is switched more than twice. This is the time required from the measurement accuracy of the membrane gas meter, and there are problems such as hindrance to convenience and the fact that there are few combustion appliances equipped with the function of pole and fire. Switching is allowed.

  Even in an electronic gas meter that is an instantaneous flow meter, the determination time for the return safety check is greatly affected by the presence or absence of a minimum flow rate classification. Ending the return safety check in an instantaneous flow meter in a short time is the greatest appeal point when compared with a conventional membrane gas meter. As means for realizing this, the general logic is to detect the instantaneous flow rate after input of the return signal, confirm the presence / absence of leakage flow rate, and complete the return safety check.

  However, when there is a leak in the minimum flow rate classification, it takes a considerably longer time after the return to stably detect the leak flow rate than in the case where the minimum flow rate combustion instrument is not set. This is a physical phenomenon that piping parameters have and cannot be dealt with by a gas meter. If it is configured with the same logic with the setting of the return safety confirmation time taking into account the setting of the minimum flow combustion equipment, the completion of the return safety check will be delayed, and as a result the appeal of the instantaneous flowmeter will be focused Will be weak. However, if priority is given to short-time determination, the probability of erroneous determination increases and there is a danger, so naturally it is not possible to make the determination accuracy of the minimum flow rate category poor.

Therefore, in the second reference example, which is useful for understanding the gist of the present invention, in order to solve the above-described problem, a stable time corresponding to each situation of the presence or absence of the minimum flow rate category is prepared internally as data. The present invention proposes a return safety confirmation method capable of making a quick and accurate determination by automatically switching parameters according to a set state (the presence or absence of an extremely small flow combustion appliance) and an electronic gas meter that implements the method.

FIG. 7 is a block diagram showing an electronic gas meter that implements a return safety confirmation method according to a second reference example that is useful for understanding the gist of the present invention . The electronic gas meter includes a flow rate monitoring unit 1, a data calculation unit 2, a data storage unit 3, a threshold value storage unit 4, a data comparison unit 5, a return signal input unit 6, a control unit 8, a cutoff unit 9, and a stable time monitoring unit. 12 is comprised.

Stabilization time monitoring unit 12 serves as a stable time monitoring means. The flow rate monitoring unit 1, the data calculating unit 2, the data storage unit 3, a threshold storage unit 4, the data comparison unit 5 and the control unit 8 acts as a carriage return safety check means.

  The flow rate monitoring unit 1 monitors the flow rate of the gas flowing through the gas flow path, and includes a flow rate sensor such as an ultrasonic sensor or a flow sensor that can detect an instantaneous flow rate. The data calculation unit 2 is supplied with a flow rate detection output from the flow rate monitoring unit 1 by flow rate sampling at a predetermined value interval, and calculates based on the supplied flow rate detection output to calculate an instantaneous flow rate.

  The data storage unit 3 stores the instantaneous flow rate calculated by the data calculation unit 2. The threshold value storage unit 4 stores a preset flow rate threshold value.

  The instantaneous flow rate threshold value is a threshold value for determining whether or not the leakage flow rate is flowing, and is set to, for example, 8.3 liters / hour (L / h).

  The data comparison unit 5 compares the instantaneous flow rate stored in the data storage unit 3 with the flow rate threshold value stored in the threshold value storage unit 4 and outputs the comparison result.

  The return signal input unit 6 includes a shut-off valve opening switch (not shown) that is turned on when a return button (not shown) is pressed. The stabilization time monitoring unit 12 monitors the presence or absence of the setting of the minimum flow rate combustion appliance, sets the return safety confirmation time to the first predetermined value when there is no setting, and sets the second longer than the first predetermined value when there is a setting. Is set to a predetermined value. The first and second predetermined values are stored as stable time parameter types 1 and 2, respectively.

  The control unit 8 outputs an instruction signal that instructs the flow rate monitoring unit 1 to perform flow rate sampling at predetermined value intervals. Further, the control unit 8 controls the shut-off valve 9 so as to close the shut-off valve or the shut-off valve controlled to open the shut-off valve in response to the input of the comparison result from the data comparison unit 5. Outputs a valve return signal. The shut-off unit 9 includes a shut-off valve that is controlled by a shut-off valve return signal or a shut-off valve close signal from the control unit 8 to open and close the gas flow path.

  The data calculation unit 2, the data storage unit 3, the threshold value storage unit 4, the data comparison unit 5, the stable time monitoring unit 12, and the control unit 8 can be configured by a microcomputer having a CPU, a ROM, and a RAM. In this case, the CPU functions as the data calculation unit 2, the data comparison unit 5, and the control unit 8, the ROM functions as the threshold value storage unit 4, and the RAM functions as the data storage unit 3 and the stable time monitoring unit 12.

  In the above configuration, when receiving the return signal from the return signal input unit 6, the control unit 8 instructs the stable time monitoring unit 12 to set the stable time. Upon receiving the instruction, the stable time monitoring unit 12 confirms the current setting state (setting of the presence / absence of the minimum flow rate combustion appliance) from the data storage unit 3, takes in the stable time parameter corresponding to the setting state, and serves as a stable time timer. Set. From the time when the stabilization time timer starts, the control unit 8 instructs the instantaneous flow rate monitoring unit 1 to perform flow rate sampling. Each sampling result is calculated by the data calculation unit 2, and the calculated instantaneous flow rate value is stored in the data storage unit 3. The stored instantaneous flow rate value is compared with the instantaneous flow rate threshold value by the data comparison unit 5, and a leak check is executed. When leakage is detected, the control unit 8 outputs a shut-off valve closing signal to the blocking unit 9, and when it is determined that there is no leakage, the return safety check is terminated and normal use is permitted.

  Next, the operation of the above-described electronic gas meter will be described with reference to the flowchart shown in FIG.

  FIG. 8 is a flowchart showing the processing operation of the return safety confirmation function.

  First, after shutting off by any shut-off function, the shut-off valve opening switch is turned on by pressing the return button, whereby the return signal from the return signal input unit 6 is input to the control unit 8 (step S61).

  Next, the control unit 8 outputs a shut-off valve return signal based on the input of the return signal (step S62). Thereby, the cutoff part 9 is controlled by the cutoff valve return signal from the control part 8, and the cutoff valve is opened.

  Next, the control unit 8 instructs the stable time monitoring unit 12 to set a stable time. Upon receiving the instruction, the stable time monitoring unit 12 confirms the current setting state (setting of presence / absence of the minimum flow combustion appliance) stored in the data storage unit 3 and determines whether or not the setting has the minimum flow combustion appliance. Is determined (step S63). When the answer is No (that is, when the setting is that there is no minimum flow combustion appliance), the stabilization time parameter type 1 is set (step S64). By setting the stable time parameter type 1, it is set to a first predetermined value T1 (for example, 60 seconds) as a stable time parameter, and a stable time timer for counting the first predetermined value T1 is started.

  On the other hand, if the answer to step S63 is Yes (that is, if there is a setting with a minimum flow rate combustion appliance), then the stabilization time parameter type 2 is set (step S65). By setting the stable time parameter type 2, the second predetermined value T2 as the stable time parameter (where T2> T1, for example, T2 = 150 seconds) is set, and the second predetermined value T2 is counted. The stabilization time timer starts.

  Next, the control unit 8 counts the first predetermined value T1 (for example, 60 seconds) set in step S64 or the second predetermined value (for example, 150 seconds) set in step S65. ) Has been exceeded (step S66). If the answer is Yes, the process proceeds to step S67.

  In step S67, the control unit 8 instructs the flow rate monitoring unit 1 to sample the instantaneous flow rate. As a result, a flow rate detection signal is output from the flow rate monitoring unit 1, calculated by the data calculation unit 2, and the calculated instantaneous flow rate value Qn is stored in the data storage unit 3.

  Next, the data comparison unit 5 determines whether or not the instantaneous flow rate Qn stored in the data storage unit 3 is larger than the instantaneous flow rate threshold value (Qn> instantaneous flow rate threshold value) (step S68). If the answer is No, a return safety confirmation signal is then output as a return safety confirmation end (step S69), and the process is then terminated.

  On the other hand, if the answer to step S68 is Yes, the control unit 8 then outputs a shut-off valve closing signal, controls the shut-off valve in the shut-off unit 9 to close, and closes the gas flow path (step S70). ), And then the process ends.

  Thus, the minimum leakage flow rate that permits return safety varies depending on whether or not the minimum flow rate combustion appliance is set. Since there is a difference in the stabilization time for detecting the minimum leakage flow rate after returning, the stabilization time is switched according to the setting of the minimum flow rate combustion appliance. The stable time parameters are stored in the data storage unit 3 in advance, and the return safety confirmation process is executed by reflecting them.

Specific effects of the second reference example in which the flow rate sampling is performed after the stable time has elapsed include the following points.
(1) The instantaneous flow rate in a stable leakage state can be measured.
(2) In the case of the flow rate sampling method immediately after the return, since the determination is made based on the flow rate in the unstable section, the probability of misjudgment increases. However, according to the second reference example , the probability of misjudgment decreases.
(3) When averaged data is adopted in the flow rate sampling method immediately after return, the data in the unstable section is also reflected, so the calculation result becomes dull, but in the second reference example According to that, such a thing is solved.

As described above, according to the second reference example , the accurate leakage flow rate can be captured by setting the stabilization time of the flow rate after returning to a different value depending on whether or not the minimum flow combustion appliance is set, In addition, the benefits of the short-time measurement of the instantaneous flow meter can be maximized, and therefore the return safety confirmation work can be carried out with the highest accuracy and speed, and the work efficiency of the gas company during construction can be improved. Can do. Further, if there is a leakage flow rate during the return safety confirmation time, it is shut off again, and if there is no leakage flow rate, the return safety check is completed, so the safety is improved.

(Third reference example)
The gas meter is equipped with a shutoff valve for shutting off the gas, but there are two situations when the shutoff event occurs. One is a case where the gas is cut off during gas use because it is judged that the situation is dangerous when an abnormality is detected during gas use, such as total flow cut off or usage time cut off. Is a case where gas is not used, such as a test shutdown. The difference between the two cases is that the pressure in the pipe on the downstream side of the meter is atmospheric pressure in the former case, and that the gas supply pressure is maintained as it is in the latter case.

  Here, when a return operation is performed after shut-off, a return safety check is performed to detect leakage. However, in the case of an S-type gas meter, a determination time of 1 minute is always required regardless of the situation. Considering the actual gas flow, in the former case described above, after returning, it is necessary to supply gas into the pipe on the downstream side of the meter, so a large flow rate is also instantaneously generated in the gas meter section. . On the other hand, in the latter case, since there is no need to supply gas downstream of the gas meter, no instantaneous flow rate change occurs. The electronic gas meter periodically samples the instantaneous flow rate, and can capture the above-described flow rate change.

Therefore, in the third reference example that is useful for understanding the gist of the present invention, it is possible to determine the situation at the time of shut-off depending on whether or not the instantaneous flow of a large flow rate at the time of return is detected. The present invention proposes a return safety confirmation method capable of making a quick and accurate determination by preparing stable time parameters as data internally and automatically switching according to each situation, and an electronic gas meter implementing the method.

FIG. 9 is a block diagram showing an electronic gas meter that implements a return safety confirmation method according to a third reference example that is useful for understanding the gist of the present invention . The electronic gas meter includes a flow rate monitoring unit 1, a data calculation unit 2, a data storage unit 3, a threshold value storage unit 4, a data comparison unit 5, a return signal input unit 6, a control unit 8, and a cutoff unit 9.

Flow monitoring unit 1, the data calculating unit 2, the data storage unit 3, a threshold storage unit 4, the data comparison unit 5 and the control unit 8 acts as a carriage return safety check means.

  The flow rate monitoring unit 1 monitors the flow rate of the gas flowing through the gas flow path, and includes a flow rate sensor such as an ultrasonic sensor or a flow sensor that can detect an instantaneous flow rate. The data calculation unit 2 is supplied with a flow rate detection output from the flow rate monitoring unit 1 by flow rate sampling at a predetermined value interval, and calculates based on the supplied flow rate detection output to calculate an instantaneous flow rate.

  The data storage unit 3 stores the instantaneous flow rate calculated by the data calculation unit 2. The threshold value storage unit 4 stores a first flow rate threshold value set in advance and a second flow rate threshold value smaller than the first flow rate threshold value.

  The first flow rate threshold value is a threshold value for determining the presence or absence of a large flow rate immediately after the return, and is set to 1000 liters / hour (L / h), for example. The second flow rate threshold value is a threshold value for determining whether or not the leakage flow rate is flowing, and is set to, for example, 8.3 liters / hour (L / h).

  The data comparison unit 5 compares the instantaneous flow rate stored in the data storage unit 3 with the first or second threshold value stored in the threshold value storage unit 4, and outputs each comparison result. . The return signal input unit 6 includes a shut-off valve opening switch (not shown) that is turned on when a return button (not shown) is pressed.

  The control unit 8 outputs an instruction signal that instructs the flow rate monitoring unit 1 to perform flow rate sampling at predetermined value intervals. Further, the control unit 8 controls the shut-off valve 9 so as to close the shut-off valve or the shut-off valve controlled to open the shut-off valve in response to the input of the comparison result from the data comparison unit 5. Outputs a valve return signal. The shut-off unit 9 includes a shut-off valve that is controlled by a shut-off valve return signal or a shut-off valve close signal from the control unit 8 to open and close the gas flow path.

  The data calculation unit 2, the data storage unit 3, the threshold value storage unit 4, the data comparison unit 5 and the control unit 8 can be constituted by a microcomputer having a CPU, a ROM and a RAM. In this case, the CPU Serves as the data operation unit 2, the data comparison unit 5, and the control unit 8, the ROM serves as the threshold storage unit 4, and the RAM serves as the data storage unit 3.

  In the above-described configuration, when receiving the return signal from the return signal input unit 6, the control unit 8 outputs a shut-off valve return signal for return to the shut-off unit 9, and shifts to the return safety confirmation mode. At the same time, the control unit 8 instructs the instantaneous flow rate monitoring unit 1 to perform flow rate sampling. Each sampling result is calculated by the data calculation unit 2, and the calculated instantaneous flow rate value is stored in the data storage unit 3. The data comparison unit 5 checks whether a large flow rate is detected in the instantaneous flow rate immediately after the return. The data comparison unit 5 outputs a determination result on the presence or absence of a large flow rate to the control unit 8. In response to the determination result, the control unit 8 employs return safety logic prepared for each to check for leakage. When leakage is detected, the control unit 8 outputs a shut-off valve closing signal to the blocking unit 9, and when it is determined that there is no leakage, the return safety check is terminated and normal use is permitted.

  Next, the operation of the above-described electronic gas meter will be described with reference to the flowchart shown in FIG.

  FIG. 10 is a flowchart showing the processing operation of the return safety confirmation function.

  First, after a shut-off by any shut-off function, the shut-off valve opening switch is turned on by pressing the return button, whereby the return signal from the return signal input unit 6 is input to the control unit 8 (step S81).

  Next, the control unit 8 outputs a shut-off valve return signal based on the input of the return signal (step S82). Thereby, the cutoff part 9 is controlled by the cutoff valve return signal from the control part 8, and the cutoff valve is opened.

  Next, the control unit 8 instructs the flow rate monitoring unit 1 to sample the instantaneous flow rate (step S83). Thereby, a flow rate detection signal is output from the flow rate monitoring unit 1, calculated by the data calculation unit 2, and the calculated instantaneous flow rate value Qo is stored in the data storage unit 3.

  Next, the data comparison unit 5 determines whether or not the instantaneous flow rate Qo stored in the data storage unit 3 is larger than the first flow rate threshold value (step S84). If the answer is no, then the stabilization time parameter type 1 is set (step S85). By setting the stable time parameter type 1, it is set to a first predetermined value T1 (for example, 60 seconds) as a stable time parameter, and a stable time timer for counting the first predetermined value T1 is started.

  On the other hand, if the answer to step S63 is yes, then, the stable time parameter type 2 is set (step S86). By setting the stable time parameter type 2, the second predetermined value T2 as the stable time parameter (where T2> T1, for example, T2 = 150 seconds) is set, and the second predetermined value T2 is counted. The stabilization time timer starts.

  Next, the control unit 8 counts the first predetermined value T1 (for example, 60 seconds) set in step S85 or the second predetermined value (for example, 150 seconds) set in step S86. ) Is exceeded (step S87), and if the answer is Yes, the process proceeds to step S88.

  In step S88, the control unit 8 instructs the flow rate monitoring unit 1 to sample the instantaneous flow rate again. As a result, a flow rate detection signal is output from the flow rate monitoring unit 1, calculated by the data calculation unit 2, and the calculated instantaneous flow rate value Qn is stored in the data storage unit 3.

  Next, the data comparison unit 5 determines whether or not the instantaneous flow rate Qn stored in the data storage unit 3 is larger than the second flow rate threshold value (step S89). If the answer is No, then a return safety confirmation signal is outputted as a return safety check end (step S90), and then the process is ended.

  On the other hand, if the answer to step S89 is Yes, the control unit 8 then outputs a shut-off valve closing signal, controls the shut-off valve in the shut-off unit 9 to close, and closes the gas flow path (step S91). ), And then the process ends.

  In this way, it is confirmed whether or not a large flow rate is detected in the instantaneous flow rate measurement performed after the return signal is input. When a large flow rate is detected, it is probable that the gas was shut off during gas use, such as shutting off the total flow rate or shutting down the usage time, and the pressure in the pipe on the downstream side of the meter was atmospheric pressure. When restoration is performed in such an environment, the timing at which leakage can be detected during the restoration safety check is not immediately after restoration, but after gas is supplied into the pipe and a certain amount of stabilization time has elapsed.

  If a large flow rate is detected immediately after the return, the presence or absence of leakage is judged based on the flow rate immediately after the return. The probability of misjudgment increases. In order to perform normal flow rate detection, it is necessary to perform leakage flow monitoring for confirmation of return safety after providing a stabilization time after return.

  On the other hand, in cases where the gas is not used, such as a test shutdown, the gas supply pressure is maintained as it is, so there is no change in flow rate, and the presence or absence of leakage can be determined by the flow rate immediately after return. . Therefore, when the large flow rate is not detected immediately after the return, the stabilization time can be shortened and the flow rate can be monitored for return safety confirmation.

As described above, according to the third reference example , the return safety confirmation work is performed more quickly and safely by setting the flow stabilization time after return to a different value depending on whether there is a large flow rate immediately after return. It is possible to improve work efficiency at the time of construction by the gas company. In addition, if there is a leakage flow rate during the return safety confirmation time, it is shut off again, and if there is no leakage flow rate, the return safety confirmation ends, so safety is improved.

As described above, the reference example and the embodiment of the present invention that are useful for understanding the gist of the present invention have been described, but the present invention is not limited to this, and various modifications and applications are possible.

For example, the values of the flow rate threshold value, the first flow rate threshold value, the second flow rate threshold value, the return safety confirmation parameter type 1 & 2, the stable time parameter type 1 & 2 and the like in the embodiment and the reference example described above are appropriately set. It can be changed.

It is a block diagram which shows the electronic gas meter which implements the return safety confirmation method which concerns on embodiment of this invention. (Embodiment) It is a flowchart which shows the flow volume presence / absence recording process of the electronic gas meter of FIG. It is a flowchart which shows the processing operation of the return safety confirmation function of the electronic gas meter of FIG. It is a block diagram which shows the electronic gas meter which implements the return safety | security confirmation method which concerns on the 1st reference example useful for understanding the main point of this invention. (First reference example) It is a flowchart which shows the interruption | blocking information recording process of the electronic gas meter of FIG. It is a flowchart which shows the processing operation of the return safety confirmation function of the electronic gas meter of FIG. It is a block diagram which shows the electronic gas meter which implements the return safety | security confirmation method which concerns on the 2nd reference example useful for understanding the main point of this invention. (Second reference example) It is a flowchart which shows the processing operation of the return safety confirmation function of the electronic gas meter of FIG. It is a block diagram which shows the electronic gas meter which implements the return safety | security confirmation method which concerns on the 3rd reference example useful for understanding the main point of this invention. (Third reference example) It is a flowchart which shows the processing operation of the return safety confirmation function of the electronic gas meter of FIG.

Explanation of symbols

1 Flow monitoring unit (part of return safety confirmation means)
2 Data calculation part (part of return safety confirmation means)
3 Data storage (part of return safety confirmation means)
4 Threshold memory (part of return safety confirmation means)
5 Data comparison part (part of return safety confirmation means)
6 Return signal input unit 7 Flow rate presence / absence monitoring unit (flow rate presence / absence monitoring means)
8 Control part (part of return safety confirmation means)
9 Blocking unit 10 Test signal input unit 11 Blocking information monitoring unit (blocking information monitoring means)
12 Stability time monitoring unit (stable time monitoring means)

Claims (5)

After the occurrence of a shut-off event in which the gas meter shut-off valve is closed to shut off the gas supply, the return safety check is performed to check the return safety when the shut-off valve is opened and the gas supply is restored based on the input of the return signal. A method,
The presence or absence of the flow rate immediately before the shutoff is monitored, and when there is no flow rate, the return safety confirmation time is set to a first predetermined value, and when there is the flow rate, the return safety confirmation time is set from the first predetermined value. A return safety confirmation method characterized by setting a long second predetermined value and confirming the return safety based on the presence or absence of a leakage flow rate during the return safety confirmation time of the first or second predetermined value. In the return safety confirmation method according to claim 1,
During the return safety confirmation time of the first or second predetermined value, when there is the leakage flow rate, the shutoff valve is closed to shut off the gas supply, and when there is no leakage flow rate, A return safety confirmation method characterized by maintaining the valve open of the shut-off valve and ending the return safety confirmation. After the occurrence of a shut-off part comprising a shut-off valve for shutting off the gas flow path and a shut-off event in which the gas supply is shut off by the shut-off valve, when the shut-off valve is opened based on the input of a return signal, the gas supply is restored. An electronic gas meter equipped with return safety check means for checking return safety,
A flow rate presence / absence monitoring means for monitoring the flow rate immediately before the shutoff is further provided,
The return safety confirmation means sets a return safety confirmation time to a first predetermined value when there is no flow based on the monitoring of the flow rate presence / absence monitoring means, and sets the return safety confirmation time when there is the flow. It is set to a second predetermined value longer than the first predetermined value, and the return safety is confirmed based on the presence or absence of a leakage flow rate during the return safety confirmation time of the first or second predetermined value. Electronic gas meter. The electronic gas meter according to claim 3, wherein
The return safety confirmation means shuts off the gas supply by closing the shutoff valve when the leakage flow rate is present during the return safety confirmation time of the first or second predetermined value, and An electronic gas meter characterized in that when there is no leakage flow rate, the shut-off valve is kept open and the return safety check is completed. The electronic gas meter according to claim 3 or 4,
The return safety confirmation means includes
A flow rate monitoring unit for monitoring an instantaneous flow rate of the gas flowing through the gas flow path;
A detection output from the flow rate monitoring unit is supplied, a data calculation unit that calculates based on the supplied detection output and calculates an instantaneous flow rate value,
A data storage unit for storing the instantaneous flow rate value calculated by the data calculation unit;
A threshold value storage unit for storing a preset flow rate threshold value;
A data comparison unit that compares the instantaneous flow rate value stored in the data storage unit with the flow rate threshold value stored in the threshold value storage unit and outputs a comparison result;
Based on the monitoring of the flow rate presence / absence monitoring means, the return safety confirmation time is set to a first predetermined value when there is no flow rate, and the return safety confirmation time is set from the first predetermined value when the flow rate is present. A long second predetermined value is set, and the instantaneous flow rate value is larger than the flow rate threshold value based on a comparison result from the data comparison unit during the return safety confirmation time of the first or second predetermined value. The shutoff valve is closed to shut off the gas supply, and when the flow rate is less than or equal to the flow rate threshold value, the shutoff valve is kept open and the return safety check is terminated. And an electronic gas meter.

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