JP2009064081A - Gas alarm shutoff device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To detect a fire or a different kind of gas from a supply gas on a gas leakage alarm side, and to transmit whether a shutoff phenomenon is leakage of the supply gas or the detection of the fire or the different kind of gas to a gas meter side, in a gas alarm shutoff system wherein the gas meter and the gas leakage alarm are connected by a signal line. <P>SOLUTION: In this gas alarm shutoff system, the gas leakage alarm 1 transmits a valve shutoff signal to the gas meter 2 when the gas leakage alarm 1 detects the leakage of the supply gas (e.g. an LP gas), and the gas meter 2 shuts off a gas supply passage when the gas meter 2 receives it, and transmits a valve shutoff answer signal showing a shutoff state of a shutoff valve to the gas leakage alarm 1. The gas leakage alarm 1 gives an alarm that the shutoff valve shuts off when receiving the valve shutoff answer signal. The gas leakage alarm 1 has a different-kind-of-gas detection part (exemplified by a CO gas sensor part 14) and/or a fire detection part 15, and transmits a valve shutoff signal after transmitting a different-kind-of-shutoff-phenomenon signal showing a different kind of shutoff phenomenon from the leakage of the supply gas to the gas meter 2 when CO gas or the fire is detected. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a gas alarm cutoff system, and more specifically, a gas meter with a built-in or external gas cutoff valve and a gas leak alarm are connected by a signal line, and the gas leak alarm and the gas meter are connected through the signal line. It is related with the gas alarm interruption | blocking system which transmitted / received the signal between.

  Conventionally, when city gas or LP gas is supplied to a residential house or the like, an electronic gas meter (also referred to as a microcomputer gas meter) is installed in the residential house or the like, and gas leakage is monitored by a gas leak alarm. A shut-off valve for shutting off the gas is installed in the gas supply path. This shut-off is performed by detecting an earthquake or abnormal flow in the microcomputer gas meter, or by detecting a gas leak from the gas leak alarm. The valve is closed.

  FIG. 5 is a block diagram showing a gas alarm cutoff system including a conventional gas leak alarm and a gas meter, and FIG. 6 is a time chart showing various signal transmission modes transmitted and received by the gas alarm cutoff system of FIG. It is.

  The gas leak alarm shut-off system in FIG. 5 has a gas leak alarm 3 and a microcomputer type gas meter (hereinafter simply referred to as “gas meter”) 4 connected by two signal lines, and the gas meter 4 is shut off from the gas supply. A shutoff valve (not shown) is connected to be controllable. The gas leak alarm device 3 is linked with a display unit 31 such as an LED for displaying energization and alarm of the own device, an LP gas sensor unit 33 for detecting LP gas, an alarm unit 32 for notifying an alarm based on the detection, and a gas meter 4. For this purpose, the input / output unit 38 includes photocouplers (PC1 and PC2), and the control unit 37 includes a CPU 37a that controls signals from each unit. The alarm unit 32 includes a speaker 32a and an amplifier (AMP) 32b for generating sound, a buzzer 32c for generating a buzzer sound, and a drive circuit 32d thereof.

  A valve shut-off signal and a power answer response signal are output from the gas leak alarm 3 to the gas meter 4 (direction A in FIG. 5). The output in the A direction is made when the photocoupler PC1 of the input / output unit 38 is turned on and off by drive control on the gas leak alarm 3 side (CPU 37a). On the other hand, the gas meter 4 outputs an answer signal such as a valve shutoff answer, a valve shutoff notice answer, a valve return safety confirmation answer, and a use permission answer to the gas leak alarm 3 and a power answer request signal. And an unconnected detection signal is output (direction B in FIG. 5). The output in the B direction is performed by turning on and off the photocoupler PC2 of the input / output unit 38 by drive control from the gas meter 4 side. In FIG. 5, both the A direction and the B direction indicate directions in which a current flows according to the voltage applied from the gas meter 4.

  The timing for outputting these signals and the transmission form thereof will be described. When the gas leak alarm 3 detects a gas leak and outputs a valve shut-off signal after a certain time, the gas meter 4 recognizes that it is a valve shut-off signal from the ON-OFF time of the signal and closes the shut-off valve of the gas meter 4. At the same time, a valve shutoff answer is sent to the gas leak alarm 3. The valve shut-off signal and the valve shut-off answer are transmitted in a form as shown in FIG. When the gas leakage alarm device 3 recognizes this valve shut-off answer, the alarm unit 32 generates a sound or buzzer sound indicating that the shut-off valve of the gas meter 4 is closed, and notifies the user of the gas.

  The valve shut-off notice answer is a signal for making a notice to close the shut-off valve set in the gas meter 4 when the gas user continues to use gas for a long time. For example, when it is 8 minutes before closing, the gas meter 4 starts sending the gas leak alarm 3. The valve return safety confirmation answer is a signal for starting transmission from the gas meter 4 to the gas leak alarm device 3 during a monitoring time for checking whether gas is flowing after the shutoff valve of the gas meter 4 is returned. The use permission answer is a signal sent from the gas meter 4 to the gas leak alarm 3 when the gas becomes usable thereafter. The valve shut-off notice answer, the valve return safety confirmation answer, and the use permission answer are transmitted in a form as shown in FIG. In response to these answer signals, the gas leak alarm 3 generates a sound and a buzzer sound from the alarm unit 32 to notify the user of the gas.

  The power answer request signal is a signal sent from the gas meter 4 side to the gas leak alarm device 3 in order to confirm whether the gas leak alarm device 3 is energized. The power answer response signal is a signal that responds to the gas meter 4 from the gas leak alarm 3 when the power is on. For example, as shown in FIG. 6C, the power answer response signal is issued after Tx from the reception of the power answer request signal. This is a signal having a width Ty. The unconnected detection signal is a signal output to the gas leak alarm 3 in order to detect whether or not the gas leak alarm 3 is connected to the gas meter 4, and this signal includes a gas leak alarm. The vessel 3 does not react.

Further, Patent Literature 1 discloses a gas leak alarm device that detects supply gas leak and transmits a gas leak alarm signal (corresponding to the above-described valve shut-off signal) to a gas meter. When this gas leak alarm device receives a shutoff notification signal (corresponding to the above-described valve shutoff answer signal) from the gas meter, the gas leak alarm signal (corresponding to the above valve shutoff signal) is received before receiving this shutoff notification signal. It is determined whether or not it has been transmitted to the gas meter, and if it was transmitted, an alarm was given that the shut-off valve was shut off due to gas leak detection. Alarm that it was cut off by earthquake detection.
Japanese Patent Publication No. 7-59977

  As described above, in the conventional gas alarm cutoff system including the technique described in Patent Document 1, the valve cutoff signal is sent to the gas meter only when the gas leak alarm detects a gas leak with respect to the “supply gas” leak. Sending.

  Therefore, if a gas that is different from the supply gas and a dangerous gas is generated, or if a fire breaks out, the gas leak alarm will not issue an alarm and the gas meter will not be affected. Since no signal is emitted, it is necessary to wait for detection of an abnormal flow rate on the gas meter installed outdoors.

  Moreover, even if the gas leak alarm is configured to detect foreign gas or fire on the side of the gas leak alarm, simply by sending a valve shut-off signal to the gas meter and controlling the shut-off valve to close, the shut-off event will be Whether it is a leak, a different gas or a fire cannot be transmitted to the gas meter.

  The present invention has been made in view of the actual situation as described above, and in a gas alarm cutoff system in which a gas meter and a gas leak alarm device are connected by a signal line, a gas different from the supply gas on the gas leak alarm side is provided. The purpose is to enable detection and fire detection, and to allow the gas meter side to communicate whether the shut-off event is a supply gas leak or a foreign gas or fire detection.

  In order to solve the above-described problems, a first technical means of the present invention includes a gas meter for measuring a flow rate of a supplied gas and a gas line connected to the gas meter by a signal line to detect leakage of the gas. And a gas shutoff valve provided in the gas supply path, and when the gas leak alarm detects the gas leak, a valve is connected to the gas meter via the signal line. When the gas meter receives the valve shut-off signal by transmitting a shut-off signal, the valve operates the shut-off valve to shut off the gas supply path, and indicates the shut-off state of the shut-off valve via the signal line A gas alarm cutoff system that transmits a shutoff answer signal to the gas leak alarm device and warns that the shutoff valve is shut off when the gas leak alarm device receives the valve shutoff answer signal. The above The leak detector has a different gas detector that detects a gas different from the supplied gas, and / or a fire detector that detects a fire, and the different gas detector and / or the fire detector When the different gas or fire is detected, the valve shut-off signal is transmitted after the heterogeneous shut-off event signal indicating the shut-off event different from the supplied gas leak is sent to the gas meter. It is a feature.

  The second technical means is characterized in that, in the first technical means, the gas meter does not execute any control when the heterogeneous cutoff event signal is received.

  According to a third technical means, in the first technical means, when the gas meter receives the heterogeneous cutoff event signal, the gas meter recognizes that a cutoff event different from the leakage of the supplied gas has occurred. It is characterized by having.

  According to a fourth technical means, in any one of the first to third technical means, the gas leak alarm includes an operation unit that performs an operation of transmitting the heterogeneous cutoff event signal and the valve cutoff signal in a pseudo manner. It is characterized by having.

  According to the present invention, in a gas alarm cutoff system in which a gas meter and a gas leak alarm are connected by a signal line, a gas different from the supply gas can be detected on the gas leak alarm side and a fire can be detected and shut off. It is possible to transmit to the gas meter side whether the event is a supply gas leak or a foreign gas or fire detection.

  FIG. 1 is a block diagram illustrating a configuration example of a gas alarm cutoff system including a gas leak alarm and a gas meter according to the present invention. A gas leak alarm cutoff system according to the present invention (hereinafter referred to as the present system) includes a gas meter 2 that measures the flow rate of a supplied gas, a gas leak alarm device 1 that detects and alarms a leak of the supplied gas, Are connected to each other by signal lines (in this example, two signal lines are illustrated).

  The gas meter 2 may be a general microcomputer type gas meter, and a shutoff valve (not shown) for shutting off the gas supply is installed in the gas supply path. The gas supply path at the installation location may be inside the casing of the gas meter 2 (that is, built in the gas meter 2) or piping outside the casing, and in any case, valve control is performed from the control unit of the gas meter 2. Can be configured. Hereinafter, although the gas supplied is illustrated as LP gas, other gas, such as city gas, may be supplied. Further, by providing the gas meter 2 with a communication function with an external center, information such as gas flow rate and abnormality detection can be transmitted to the external center.

  The gas leak alarm device 1 includes a display unit 11, an alarm unit 12 (speaker 12a, AMP 12b, buzzer 12c, drive circuit 12d, etc.), an LP gas sensor unit 13, a control unit 17 including a CPU 17a, and an input / output unit 18. Regarding these components, the display unit 31, the alarm unit 32 (speaker 32a, AMP 32b, buzzer 32c, drive circuit 32d, etc.), the LP gas sensor unit 33, the control unit 37 (CPU 37a, etc.), and the input / output shown in FIG. This is the same as the unit 38, and the description thereof is omitted. However, although control of each part in the control part 17 is mentioned later, it differs from that of the control part 37.

  The gas leak alarm 1 further includes a CO gas sensor unit 14, a fire detection unit 15, and a switch 16, which are connected to the CPU 17a. The CO gas sensor unit 14 is an example of a different gas detection unit that detects a gas different from the supply gas exemplified in the LP gas. CO is a toxic gas generated in the event of a fire or fire extinguishing an oil stove. Note that the gas leak alarm 1 may be configured to simultaneously detect a toxic gas other than CO and a gas that may ignite. The fire detection unit 15 includes a temperature sensor that detects a fire.

  Hereinafter, the gas leak alarm device 1 will be described as including all of the CO gas sensor unit 14, the fire detection unit 15, and the switch 16, but the gas leak alarm unit 1 of this system includes the CO gas sensor unit 14 and the fire detection unit 15. Any one of these may be provided. The switch 16 is not an essential component of the present system, but is preferably provided as will be described later.

  FIG. 2 is a time chart showing an example of the transmission form of various signals transmitted and received when the supply gas (here, LP gas) leak is detected in the gas alarm cutoff system of FIG.

  Referring to FIG. 2, the LP gas sensor unit 13 detects normal LP gas leakage and notifies the CPU 17a. For example, LP gas leakage is detected at a predetermined concentration or more. At this time, the CPU 17a shifts from the monitoring state to the alarm state. Then, when the LP gas leak continues for a certain time T1 from this transition (that is, after the LP gas leak occurs), the CPU 17a sends a valve shut-off signal (LP gas leak valve shut-off to the gas meter 2 via the signal line). The input / output unit 18 is controlled to transmit (output) a signal. This output may be executed when the photocoupler PC1 of the input / output unit 18 is turned on and off by drive control by the CPU 17a as illustrated in FIGS. In FIG. 2, the valve shut-off signal is illustrated as a signal that is turned on for a certain time T2 and turned off for a certain time T2.

  When the gas meter 2 discriminates the ON / OFF time of this valve shut-off signal and recognizes that it is a valve shut-off signal, the gas meter 2 operates (closes control) the shut-off valve of the gas meter 2 to shut off the gas supply path, and the gas leak alarm A valve shutoff answer indicating the shutoff state of the shutoff valve is transmitted (output) to the device 1 via the signal line. Here, the gas meter 2 checks the state of the photocoupler PC1 with a short pulse at a constant time interval in order to measure the ON-OFF time in order to prevent the internal battery from being consumed. It may be determined whether the ON-OFF time is correct. Further, as illustrated in FIGS. 5 and 6, this output may be executed when the photocoupler PC <b> 2 of the input / output unit 18 is turned on and off by drive control from the gas meter 2 side.

  When the gas leak alarm 1 receives the valve shutoff answer signal and recognizes that it is a valve shutoff answer, an alarm such as a sound or a buzzer sound indicating that the shutoff valve of the gas meter 2 is closed is generated from the alarm unit 12. And inform the user of the gas.

  FIG. 3 is a time chart showing an example of a transmission form of various signals transmitted and received when a different gas (here, CO gas) is detected or when a fire is detected in the gas alarm cutoff system of FIG.

  Referring to FIG. 3, when any one of the CO gas sensor unit 14 and the fire detection unit 15 detects the occurrence of a cutoff event (CO gas and / or fire) different from the normal LP gas leak, Tell the CPU 17a. For example, CO gas is detected at a predetermined concentration or more, and fire is detected at a predetermined temperature or more.

  Also at this time, the CPU 17a shifts from the monitoring state to the alarm state. The CPU 17a then transmits (outputs) a different type of cutoff event signal to the gas meter 2 via a signal line after a certain time Ta from this transition (that is, after a different type of cutoff event occurs). To control. Here, the heterogeneous shut-off event signal is a signal indicating a different sort of shut-off event from the supply gas leakage, and indicates a signal that is a heterogeneous shut-off event for the gas meter 2. FIG. 3 shows a signal for turning on the heterogeneous blocking event signal for a predetermined time Tb1. This output may also be executed by turning on / off the photocoupler PC1 of the input / output unit 18 by drive control by the CPU 17a.

  The CPU 17a further controls the input / output unit 18 to output a valve shut-off signal (the same signal as the above-described LP gas leak valve shut-off signal) to the gas meter 2 via a signal line after a predetermined time Tc has elapsed.

  As described above, when CO gas or fire is detected, the above-described valve shut-off signal (T2) is transmitted after the dissimilar shut-off event signal (Tb1 only ON) indicating the shut-off event different from LP gas leak is transmitted to the gas meter 2. Only repeats ON after only ON and T2 OFF). In particular, in order to keep the period from the transition to the alarm state to the output of the valve shut-off signal constant, the heterogeneous shut-off event signal is transmitted a predetermined time before the valve shut-off signal is transmitted as in the above example. It is preferable to control. At this time, naturally, Ta <T1, but if the period until the output of the valve shut-off signal is not kept constant, Ta may be arbitrary (however, depending on the values of Tb1 and Tc, Ta ≠ T1) Is preferred).

  The gas meter 2 that has recognized this valve shut-off signal similarly shuts off the gas supply path and transmits a valve shut-off answer indicating the shut-off state of the shut-off valve to the gas leak alarm 1, and the gas that has recognized this valve shut-off answer. The leak alarm 1 generates an alarm indicating that the shut-off valve is closed from the alarm unit 12 and notifies the user of gas usage.

  Here, the gas meter 2 (for example, in its control unit) is provided with a recognition means for recognizing the above-described different type interruption event signal (that is, the above-mentioned fixed time Tb1), so that the gas leak alarm 1 side to the gas meter 2 is provided. It is possible to transmit different kinds of shut-off events that need to be shut down due to CO gas and fire detection. That is, the gas meter 2 provided with this recognition means can determine information other than normal LP gas leakage on the gas meter 2 side in conjunction with the control of the gas leakage alarm 1. Thereby, the gas meter 2 can transmit more detailed information such as CO gas and fire detection as display on the display unit provided and communication information to the outside such as an external center.

  Furthermore, by enabling the gas meter 2 to transmit a shut-off event, the gas leak alarm 1 responds to the shut-off event only by configuring the gas meter 2 to output a valve shut-off answer corresponding to the shut-off event. As a result, a type of alarm corresponding to the valve shut-off answer can be issued. Further, in a system in which a plurality of gas leak alarms 1 are connected to the gas meter 2, the gas leak alarms 1 other than the gas leak alarms 1 that have issued the valve shut-off signal (and the heterogeneous shut-off event signal) also have CO gas and More detailed information such as fire detection can be transmitted, and even those gas leak alarms can issue alarms according to shut-off events.

  On the contrary, the above-described different type of shut-off event signal may be a signal that does not execute any control even when the gas meter receives (a signal that cannot be reacted). The signal that the gas meter cannot react with is a signal that is not determined to be a signal such as a valve cutoff signal in the gas meter. In particular, it is preferable that only an existing gas meter different from the gas meter not provided with the above-described recognition means be a signal that cannot react, and this signal is applied to an already installed gas meter or a gas leak alarm cutoff system including the same. The signal has no effect. What is necessary is just to employ | adopt what made the above-mentioned fixed time Tb1 the same as T2, and made Tc> T2 as a different kind | species interruption | blocking event signal.

  By adopting such a heterogeneous shut-off event signal, even a gas meter that has already been installed and does not recognize the heterogeneous shut-off event signal will not malfunction due to misrecognition and can be safely linked regardless of the shut-off event. It becomes possible to block. Further, the heterogeneous shut-off event signal represented by the predetermined time Tb1 may be an ON-OFF signal whose time is changed as long as it is a signal that is not erroneously recognized by an already installed gas meter. For example, as illustrated in FIG. 3, there is a signal that opens time Tb <b> 2 during time Tb <b> 1 and turns on.

  Moreover, it is preferable to have the operation part which performs operation which transmits the above-mentioned different kind | species interruption | blocking event signal and valve control signal in spite of which the gas leak alarm 1 of any structure mentioned above. A switch 16 is given as an example of the operation unit. By operating from the outside of the gas leak alarm 1 by the switch 16, it is possible to easily transmit a signal as shown in FIG. 3 (heterogeneous shut-off event signal and subsequent valve shut-off signal). It is possible to immediately confirm the recognition status of the gas meter 2 that can recognize the different types of interruption event signals.

  FIG. 4 is a flowchart for explaining an operation example of the control unit (CPU) in the gas alarm cutoff system of FIG. An example of the operation of this system as described above will be described from a state in which the gas leakage alarm device 1 is energized and the CPU 17a of the control unit 17 is activated.

  First, until the respective sensors of the LP gas sensor unit 13, the CO gas sensor unit 14, and the fire detection unit 15 are stabilized, an initial ringing stop period (for example, about 1 minute) is set or the initial ringing is not started. It is checked whether the ringing stop period has elapsed (step S1).

  If it is after the initial ringing stop period has elapsed in step S1 (in the case of NO), it is checked whether CO gas or fire is detected from the CO gas sensor unit 14 and the fire detection unit 15 (step S2). If not detected in step S2, it is checked whether LP gas leakage is detected by the LP gas sensor unit 13 (step S3). If LP gas leakage is not detected, the process returns to step S2, and if detected, the process proceeds to step S4.

  In step S4, it is checked whether or not the LP gas leak detection state has continued and a predetermined time T1 has elapsed. T1 is measured by a timer provided in the control unit 17, and may be reset when no LP gas leak is detected or after T1 has elapsed. If the predetermined time T1 has not elapsed in step S4, the process returns to step S2, and if it has elapsed, a valve cutoff signal is output to the gas meter 2 (step S5). In addition, it returns to step S2 also after the process of step S5.

  If CO gas or fire is detected in step S2, it is determined whether or not it has continued for a predetermined time Ta (step S6). Ta is measured by a timer provided in the control unit 17, and may be reset when both CO gas and fire are no longer detected, or after Ta has elapsed. If it has not elapsed in step S6, the process returns to step S2, and if it has elapsed, a heterogeneous blocking event signal (a signal that is turned on for a certain time Tb1 or turned on for a certain time Tb2 after being turned on) is output ( Step S7). Subsequently, it is determined whether or not a fixed time Tc has elapsed since the completion of the output (step S8). If it has elapsed, the process proceeds to step S5 and a valve shut-off signal is output. On the other hand, if it has not elapsed, the process returns to step S2. Tc is measured by a timer provided in the control unit 17, and may be reset when the output is completed in step S7 or after the elapse of Tc.

  If it is determined in step S1 that the initial ringing stop time has not elapsed, it is checked whether or not the switch 16 has been pressed (step S9). After outputting the shut-off event signal, the valve shut-off signal is output when a predetermined time Tc has elapsed (step S10). By performing the processes of steps S9 and S10 within the initial ringing stop period as described herein, there is no influence on the gas meter that has already been installed, and the gas meter 2 that can recognize the heterogeneous blocking event signal is recognized. The actual detection can be performed after checking the condition. Note that when the switch 16 is pressed at the timing after the initial ringing stop time elapses, the pressing operation may be ignored. However, since a test during such normal operation can also be assumed, The transmission of the interruption event signal may be executed.

It is a block diagram which shows the example of 1 structure of the gas alarm interruption | blocking system provided with the gas leak alarm device and gas meter based on this invention. It is a time chart which shows an example of the transmission form of the various signals transmitted and received at the time of the gas alarm interruption | blocking system of FIG. It is a time chart which shows an example of the transmission form of the various signals transmitted / received at the time of the detection of a different gas in the gas alarm interruption | blocking system of FIG. It is a flowchart for demonstrating the operation example of the control part in the gas alarm interruption | blocking system of FIG. It is a block diagram which shows the gas alarm interruption | blocking system provided with the conventional gas leak alarm device and the gas meter. It is a time chart which shows the transmission form of the various signals transmitted / received by the gas alarm interruption | blocking system of FIG.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 ... Gas leak alarm device, 2 ... Gas meter (microcomputer type gas meter), 11 ... Display part, 12 ... Alarm part, 12a ... Speaker, 12b ... Amplifier (AMP), 12c ... Buzzer, 12d ... Drive circuit, 13 ... LP gas sensor , 14 ... CO gas sensor unit, 15 ... fire detection unit, 16 ... switch, 17 ... control unit, 17a ... CPU, 18 ... input / output unit.

Claims (4)

A gas meter for measuring the flow rate of the gas to be supplied, a gas leak alarm device connected to the gas meter by a signal line to detect and alarm the gas leak, and a gas cutoff valve provided in the gas supply path And
When the gas leak alarm detects the gas leak, the gas leak alarm transmits a valve shut-off signal to the gas meter via the signal line, and when the gas meter receives the valve shut-off signal, Actuate to shut off the gas supply path, and send a valve shutoff answer signal indicating the shutoff state of the shutoff valve to the gas leak alarm device via the signal line, and the gas leak alarm device transmits the valve shutoff answer signal. A gas alarm shut-off system that warns that the shut-off valve is shut off when a signal is received,
The gas leak alarm has a different gas detector that detects a gas different from the supplied gas, and / or a fire detector that detects a fire,
When the different gas or fire is detected by the different gas detection unit and / or the fire detection unit, a different type cutoff event signal indicating a different type of cutoff event from the leakage of the supplied gas is transmitted to the gas meter. A gas alarm shut-off system characterized in that the valve shut-off signal is transmitted later.   2. The gas leak alarm shut-off system according to claim 1, wherein the gas meter does not perform any control when receiving the heterogeneous shut-off event signal.   The gas leak alarm shut-off system according to claim 1, wherein the gas meter recognizes that a shut-off event different from the leak of the supplied gas has occurred when the heterogeneous shut-off event signal is received. A gas leak alarm cutoff system characterized by comprising means.   The gas leak alarm cutoff system according to any one of claims 1 to 3, wherein the gas leak alarm is an operation for performing an operation of transmitting the heterogeneous cutoff event signal and the valve cutoff signal in a pseudo manner. A gas leak alarm shut-off system characterized by having a section.

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