JP2008108038A - Gas leak warning system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a gas leak warning system capable of appropriately outputting a warning output for a gas apparatus according to the condition of usage by people. <P>SOLUTION: The gas leak warning system is configured in such a manner that a gas meter 4 and a gas leak alarm 1 arranged corresponding to a plurality of gas apparatuses are connected so that they can communicate with each other. The gas meter 4 specifies the gas consumption status of each gas apparatus, and a human detection sensor 34 disposed on the gas leak alarm 1 detects a person around the corresponding gas apparatus 6. The gas leak warning system is also configured so that an abnormal usage state of a specific gas apparatus 6 is determined assuming that the gas apparatus 6 is consuming gas, and there is no person detected around it. An alarm is output when an abnormal usage state is detected. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to a gas leak alarm system that warns of forgetting to turn off gas in a gas appliance.

Japanese Patent Application No. 2002-171362

  Conventionally, a gas leak alarm is installed in a room such as a kitchen where a gas appliance such as a stove is installed, or a living room where a gas appliance such as a gas stove is used, and is generated from the gas appliance used in the room. It is configured to detect a combustion gas or incomplete combustion gas, and issue an alarm when this reaches a specified level.

  By the way, regarding the alarm output when using such gas equipment, it is determined whether the gas equipment itself is used safely, as well as the gas leak alarm that detects the gas generated from the gas equipment and outputs an alarm. Therefore, there is a need for a technology that outputs an alarm according to the situation. For example, an alarm such as forgetting to turn off the gas. However, in order to establish such a technique, a technique for specifying the usage status of gas equipment is indispensable.

  Patent Document 1 discloses a technique for determining whether a gas device is in use by connecting a gas leak alarm device to a gas meter. However, with this technology, even if it can be determined that the gas equipment is in use, the use status is specified whether it is a situation where people are using it safely and whether it is forgotten to turn off the gas. It does n’t work.

  This invention is made | formed in view of the said subject, and it is providing the gas leak alarm system which can output the alarm output with respect to gas equipment appropriately according to the use condition by a person.

Means and actions / effects for solving the problems

In order to solve the above problems, the gas leak alarm system of the present invention is:
Gas leak having gas concentration abnormality alarm output means for detecting the gas concentration in the room where the gas equipment is installed with a gas sensor and outputting a gas concentration abnormality alarm when the gas concentration exceeds a predetermined threshold level An alarm,
A gas meter for detecting the flow rate of gas supplied to the gas appliance;
A gas consumption state detection means for detecting whether or not the gas device is in a gas consumption state based on a gas flow rate detected by the gas meter;
A person detecting means for detecting a person existing around the gas appliance;
Based on the detection state of the gas consumption state detection means and the person detection means, the gas equipment is predetermined on the condition that the gas equipment is in the gas consumption state and no person is detected around the gas equipment. An abnormal use state determination means for determining whether or not an abnormal use state exists;
An abnormal use state alarm output means for outputting an abnormal use state alarm for notifying that the gas leak alarm device is in an abnormal use state when it is determined to be in an abnormal use state;
It is provided with.

  Basically, it is not safe to use gas equipment without human monitoring. According to the present invention described above, a predetermined abnormal use state of the gas device on the assumption that the gas device is consuming gas (gas consumption state) and no person is detected around the gas device. Is determined, and an alarm is output when it is determined to be in an abnormal use state. Thereby, an alarm can be output appropriately when the gas appliance is used.

  The abnormal use state determination means in the above configuration is used abnormally when the detection state by the gas consumption state detection means is switched from the gas non-consumption state to the gas consumption state while the human detection means is not detecting a person. It can be configured to determine that the state is established. According to this configuration, it is possible to output an alarm for a situation where the gas device starts consuming gas without a person.

  In addition, the abnormal use state determination means is also in an abnormal use state when the gas detection state detected by the gas consumption state detection means continues for a predetermined threshold time while the human detection means is not detecting a person. It can be configured to determine that is established. According to this configuration, an alarm can be output when the gas device forgets to turn off the gas.

  In addition, when the abnormal detection state alarm is output and the human detection means detects a person, the abnormal usage state alarm is stopped after the predetermined continuous output period has elapsed. A status alarm stop means can be provided. According to this configuration, if a person is detected around the gas equipment during the output of the abnormal use state alarm, it can be expected that the person will notice the alarm and take some action, so a certain output period has passed. Thereafter, the alarm can be automatically stopped to prevent unnecessary alarm output from continuing.

  Also, in the present invention, a plurality of gas devices are installed, the human detection means is provided corresponding to the plurality of gas devices, and the gas meter registers a plurality of gas devices in advance, and for each registered gas device. , Having individual flow rate detection means for detecting the consumed gas flow rate, and whether the gas consumption state determination means is in a gas consumption state for each gas device based on the gas flow rate for each gas device detected by the gas meter The abnormal use state determination means is based on the condition that the gas device determined to be in the gas consumption state by the gas consumption state determination means and the person detection means not detecting a person correspond to each other. As described above, it can be determined whether or not the gas appliance is in a predetermined abnormal use state. According to this configuration, it is possible to specify which of the plurality of gas devices is used based on the presence or absence of human detection. In addition, it is possible to identify with high probability whether or not these multiple gas appliances are being used under human monitoring, and appropriate warnings will be provided for specific abnormal usage conditions that are not being used under human monitoring. Can be given.

  The abnormal use state alarm output means is provided corresponding to a plurality of gas devices, and can output an abnormal use state alarm when it is determined that the corresponding gas device is in an abnormal use state. According to this configuration, each of the plurality of gas appliances is provided with the human detection means and the abnormal use state alarm output means, so there is a gas appliance in which gas is consumed in the absence of a person in the vicinity. In such a case, since an alarm is output from the abnormal use state alarm output means corresponding to the gas device, the user can easily identify the gas device in the abnormal use state.

  Further, the abnormal use state determination unit can include a threshold time change unit that sets a different threshold time according to a gas appliance that is a target for determining the abnormal use state. Thereby, the continuous use permissible time (threshold time) according to every gas equipment can be defined, and when each gas equipment exceeds this, an alarm can be outputted. Further, since the gas equipment being used can be estimated based on the gas flow rate detected by the gas meter, particularly based on a predetermined flow rate classification, for example, the gas flow rate is determined according to the gas flow rate detected by the gas meter. The threshold time can also be changed according to the flow rate classification to which it belongs.

  Further, the gas concentration abnormality alarm output means and the abnormal use state alarm output means can be shared by a common alarm output unit. Since the alarm output unit is shared, there is a cost advantage.

  The gas leakage alarm device may have an alarm main body in which an alarm output unit, a gas sensor, and a human detection unit are integrally incorporated in a casing. According to this configuration, the gas leak alarm of the corresponding gas device, the monitoring of the usage status of the corresponding gas device by the person, and the corresponding operation can be performed only by arranging the gas leak alarm device having the alarm device body corresponding to the gas device. All alarms regarding abnormal use of gas equipment can be realized. There is also an advantage that it is easy to specify a gas device when an alarm is output.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.
FIG. 1 is a schematic view showing an embodiment of the gas leak alarm system of the present invention. The gas leak alarm system 100 in FIG. 1 includes a gas supply facility 3, a gas meter 4, a gas leak alarm 1 (1a, 1b), and a gas device 6 (6a, 6b).

  The gas supply facility 3 adjusts the high-pressure gas in the gas container with a pressure regulator, and supplies the high-pressure gas to the outside through a gas pipe 7 having a closing cock. The gas meter 4 measures the flow rate of the gas supplied from the gas supply facility 3. The gas whose flow rate has been measured by the gas meter 4 is supplied to the gas devices 6a and 6b installed in different rooms via the gas pipeline 7 having a branch portion. The gas leak alarms 1 a and 1 b are attached to the respective rooms where the gas devices 6 a and 6 b are installed, and each of them is electrically connected to the gas meter 4. In the present embodiment, the gas appliance 6a is a kitchen facility such as a gas stove and is installed in the kitchen together with the gas leak alarm 1a, and the gas leak alarm 6b is a heating appliance such as a gas stove and the living room, etc. Is installed. That is, the gas device 6a and the gas leak alarm 1a are provided correspondingly, and the gas device 6b and the gas leak alarm 1b are provided correspondingly.

  FIG. 2 is a block diagram showing an electrical configuration of the gas leak alarms 1a and 1b. The gas leak alarms 1a and 1b are both configured in the same manner, and control the gas concentration of the gas to be detected in the room in which the control unit 10 driven by the power supply from the power supply unit 30 and the gas appliance 6 are installed. A gas sensor 31 to detect, a display unit 32 that outputs alarm contents so as to be visible as an alarm output unit, an alarm sound output unit 33 that is a speaker that outputs an alarm sound, and a human sensor that detects a person in the installed room 34 and a gas meter interface (hereinafter referred to as a gas meter I / F) 25. The gas meter I / F 25 is communicably connected to the gas meter 4 via the communication line 2. These are integrally incorporated in the casing to form the alarm main bodies 1A and 1B. The gas leak alarms 1a and 1b output a gas concentration abnormality alarm from the display unit 32 and the alarm sound output unit 33 when the gas concentration detected by the gas sensor 31 exceeds a predetermined threshold level. It is configured.

  The control unit 10 includes a CPU 11, a ROM 13 for storing various programs, a RAM 12 having a work memory used for program execution, an input / output unit (I / O in the figure) 15, a timer 16, and a bus for connecting them. It is configured as a well-known microcomputer provided with a line 14, and it is determined whether or not the gas concentration of the gas to be detected detected by the gas sensor 31 exceeds a predetermined threshold level, and the gas concentration exceeds the threshold level. When exceeding, the gas concentration abnormality alarm (gas leakage abnormality) alarm is output from the display unit 32 and the alarm sound output unit 33 which are alarm output units. The ROM 13 is constituted by a nonvolatile memory, and the ID of the human sensor 34 incorporated in each gas leak alarm 1a, 1b and the above threshold level are registered in the ROM 13.

  The gas sensor 31 detects the flow rate of the gas supplied to the gas device 6, and is a known semiconductor using a semiconductor type gas sensitive body in this embodiment. The gas sensor 31 is connected to the input / output unit 15 of the control unit 10 via the gas sensor control unit 21. In this gas sensor 31, the gas sensitive body is heated by the heater, and a detection signal reflecting the resistance value of the gas sensitive body at that time is output to the gas sensor control unit 21 as a sensor output corresponding to the concentration of the gas to be detected. The gas sensor control unit 21 compares the input detection signal with a predetermined threshold value (threshold level) by a comparator or the like, and then the gas is input to the input / output unit 15 of the control unit 10 when the threshold value is not exceeded. A level signal indicating that the concentration is at a normal level is output. If the threshold value (threshold level) is exceeded, a level signal indicating that the gas concentration is at an abnormal level (abnormal gas concentration) is output. Note that a known gas sensor having another detection method may be used instead of the semiconductor gas sensor.

  The display unit 32 is configured as a light emitting unit such as an LED, and based on the display control unit 22 receiving an alarm output command from the control unit 10, a gas concentration abnormality alarm or an abnormal use state alarm to be described later is determined depending on its lighting state. Discriminately output. For example, a gas concentration abnormality alarm and an abnormal use state alarm are output by switching from a non-lighting state to a lighting state, or by switching the lighting color or lighting pattern to a different one from the normal time. Moreover, a well-known liquid crystal display can be adopted as the display unit 32, and a gas concentration abnormality alarm can be output on a screen display. In this case, an LCD (Liquid Crystal Display) that forms a display screen and an LCD control circuit that is a driver circuit for the LCD are configured. The LCD control circuit 22 drives the LCD based on a display command and display screen data transmitted from the control unit 10. As the display unit 32, an organic EL (ElectroLuminescence) display or an inorganic EL display may be employed.

  The alarm sound output unit 33 is configured as a speaker, and based on the reception of the alarm output command from the control unit 10 by the alarm sound output control unit 23, a gas concentration abnormality alarm or an abnormal use state alarm described later is output as a buzzer sound. To do. Also, these may be output from a speaker. Specifically, a memory (for example, the ROM 13 of the control unit) that stores a sound source of alarm sound related to each alarm, and a well-known D / A conversion unit (not shown) that converts the sound source stored in the memory into analog data; The analog data can be configured to include a well-known amplifier circuit (not shown) for setting the analog data to a predetermined volume, and the analog data can be transmitted from a speaker.

  In addition, the gas leak alarm 1 in this embodiment comprises the display part 32 and the alarm sound output part 33 as an alarm output part. The display unit 32 and the alarm sound output unit 33 are also used as a common alarm output unit that executes both outputs of the gas concentration abnormality alarm and the abnormal use state alarm. In this embodiment, the control unit 10 functions as a gas concentration abnormality alarm output means in the present invention together with a display unit 32 and an alarm sound output unit 33 described later, and detects a gas consumption state in the present invention together with a gas sensor 31 described later. Functions as a means.

  The human sensor 34 is a human detection unit that detects a person existing in a predetermined detection target area, and is connected to the input / output unit 15 of the control unit 10 via the human sensor control unit 24. The human sensor 34 of the gas leak alarm 1a is associated with the gas device 6a, and the human sensor 34 of the gas leak alarm 1b is associated with the gas device 6b. And the human sensor 34 makes the area which can detect the person who uses the gas equipment 6 corresponding to the said gas leak alarm device 1 the detection target area in the circumference | surroundings of the corresponding gas leak alarm device 1. Installed. The human sensor 34 in the present embodiment is an infrared sensor that generates a detection signal in response to infrared rays emitted from a human body. The human sensor control unit 24 compares the input detection signal with a predetermined threshold (threshold level) using a comparator or the like, and if the threshold is not exceeded, a level signal indicating that no person is present In the case of exceeding, the control circuit outputs a level signal indicating the presence of a person to the input / output unit 15.

  As the human sensor 34, an acoustic sensor that detects the presence of a person by detecting the sound of a person walking from a microphone or the like, a light-blocking optical sensor that detects light blocking by facing a light source and an optical sensor, radio waves, super A reflective sensor that receives a reflected wave from a person using sound waves or the like, and further, a person may be detected by performing image analysis on a captured image of a detection target area.

  These gas leak alarms 1a and 1b are communicably connected to the gas meter 4 via the gas meter I / F 25 and the communication line 2. FIG. 3 is a block diagram showing an electrical configuration of the gas meter 4.

  The gas meter 4 includes a control unit 40 that is driven by power supply from the power supply unit 60, a gas flow rate sensor 61 that measures a gas flow rate, a meter display unit 62 that displays various measurement values based on the measured gas flow rate, A shut-off valve 63 and a gas leak alarm interface (hereinafter referred to as a gas leak alarm I / F) 55 are provided. The gas leak alarm I / F 55 is communicably connected to the gas leak alarm 1 via the communication line 2. These are integrally incorporated in the housing to form a meter body 4Z.

  The control unit 40 includes a CPU 41, a ROM 43 for storing various programs, a RAM 42 having a work memory used when executing the program, an input / output unit (I / O in the figure) 45, a timer 46, and a bus connecting them. It is configured as a well-known microcomputer having a line 44, and displays the integrated value of the gas flow rate measured by the gas flow rate sensor 61 on the meter display unit 62.

  The gas meter 4 in this embodiment is a well-known gas meter with an individual integration function (for example, Japanese Patent Application Laid-Open No. 2002-171362) that can individually integrate the flow rate of gas supplied to the plurality of gas devices 6a and 6b. The ROM 43 stores an individual flow rate integration program 43a for executing the individual integration. The individual integration process by the program 43a identifies the gas device 6 that is consuming the gas based on the flow rate classification of the gas flow rate detected by the gas meter 4, and detects the detected gas flow rate for each identified gas device 6. Accumulate. In addition, the individual integration process uses not only the flow rate classification but also the instantaneous gas flow rate and its consumption duration as parameters for identifying the gas equipment in use, and the gas equipment in use is identified based on these parameters. , Its specific accuracy can be increased.

  The ROM 43 is composed of a non-volatile memory. The ROM 43 has a gas device ID list 43c in which IDs of a plurality of gas devices 6 (6a, 6b) as gas supply destinations are registered, and is determined in advance. The flow rate classification list (or in-use gas equipment specifying parameter list) 43d in which the flow rate classifications are registered is stored.

  The gas flow rate sensor 61 is a gas flow rate detection unit that detects the flow rate of gas per unit time associated with the use of the gas devices 6a and 6b. In the gas flow rate sensor 61 in this embodiment, a pulse output is made every time a predetermined flow rate of gas flows, and the control unit 40 counts this pulse output to integrate the gas flow rate.

  The meter display unit 62 may be configured to include a known mechanical flow rate display mechanism. However, the meter display unit 62 in the present embodiment is a known liquid crystal display, and is an LCD (Liquid Crystal) that forms a display screen. Display) and an LCD control circuit which is a driver circuit for the LCD. The LCD control circuit 52 drives the LCD based on a display command and display screen data transmitted from the control unit 10. The meter display unit 62 is not only an organic EL (ElectroLuminescence) display, an inorganic EL display, and an electronic display of a measured value (indicated value of an electronic water meter). An expression may be used. The meter display unit 62 includes an integrated value of the gas flow rate of the gas devices 6a and 6b measured by the gas flow rate sensor 51 (a gas flow count count display for each gas device) and a total integrated gas flow value thereof. Gas flow information can be displayed.

  The shutoff valve 63 shuts off the gas supply from the gas supply unit 3 to the gas devices 6a and 6b, and is driven to open and close when the shutoff valve control unit 53 receives an input of the shutoff valve drive signal from the control unit 40. . Specifically, based on the gas flow rate value (gas flow rate integrated value) measured by the gas flow rate sensor 51, the control unit 40 uses a predetermined threshold time (continuous use prohibition time) T3 that is determined in advance. When it is determined that the valve has exceeded, a shut-off valve drive signal for closing the shut-off valve 63 is output to the shut-off valve control unit 53, and the shut-off valve 63 is closed. The threshold time T3 is determined for each flow rate category obtained by dividing the detectable flow rate range into a plurality of ranges. For example, a flow rate classification of 21 to less than 63 l / h, a flow rate classification of 2-1 to 63 l / h, a flow rate of 2-2 to 63 to less than 125 l / h, a flow rate of 2-3 to 125 to less than 210 l / h, ..., there are 15 flow rate segments, such as a flow rate segment 13 of 1460 or more. In the present embodiment, the allowable continuous time for each flow rate segment is stored in a form corresponding to the flow rate category registered in the flow rate category list 43d of the ROM 43.

  In the gas leak alarm system 100 of the present embodiment configured as described above, it is possible to more accurately identify the gas device 6 that is in use (gas consumption state) in the gas meter 4. Specifically, the CPU 41 executes the in-use gas device specifying program 43b stored in the ROM 43 of the gas meter 4, whereby the in-use gas device 6 is specified. Since the information related to the specified gas device 6 is written in a predetermined storage area of the RAM 42 (hereinafter referred to as an in-use gas device storage unit), the gas leak alarm 1 side can also refer to this information. It is possible to specify the gas device 6 in use.

  FIG. 4 is a flowchart showing the flow of the in-use gas device identification program 43b. When the in-use gas device identification program 43b is executed, first, in S10, the gas device 6 that is consuming gas is identified. Specifically, the gas device 6 that is being integrated is specified by the separate flow rate integration program 43a that is continuously executed separately, and the ID of the gas device 6 is read from the gas device ID list 43c. In S11, the detection result is acquired from the plurality of gas leak alarms 1 having the human sensor 34. Specifically, the gas meter 4 transmits a detection result transmission request signal for transmitting the detection results of the human sensors 34 to the plurality of gas leak alarm devices 1a and 1b having the human sensors 34, and transmits them. The received gas leak alarms 1a and 1b transmit the respective detection results to the gas meter 4 together with their own IDs as reply signals to the request signals.

  In S12, it is determined whether or not the ID of the gas device 6 acquired in S11 and the ID of the human sensor 34 acquired in S12 correspond to each other. Specifically, in the gas appliance 6 and the human sensor 34, the corresponding IDs are assigned to the corresponding ones, and therefore, the match / mismatch is determined. If they do not match, the program ends. On the other hand, if they match, the process proceeds to S13, and the fact that the gas device 6 with the ID is in use is stored in the RAM. Specifically, a usage determination flag 42a is provided as a usage status storage unit that stores the usage status of the gas for each gas device 6 registered in the gas device ID list 43c, and the corresponding gas device 6 is in use. If it is present, “1” is set, and if not in use, “0” is set. In S13, the use determination flag 42a of the gas appliance 6 corresponding to the ID acquired in S10 is set from “0” to “1”. Subsequently, in S14, when a signal (integration stop information) relating to the integration stop of the gas appliances 6a and 6b is received in S10, the use determination flag 42a set to “1” in S13 is returned to “0”. . And this program is complete | finished. The program 43a is repeatedly executed at predetermined time intervals.

  By executing this in-use gas device identification program 43b, it is determined whether the gas device 6a, 6b is currently in use (whether it is in a gas consumption state or a gas non-consumption state). It can be easily specified by referring to the flag 42a. The in-use gas equipment specifying unit functions by executing the in-use gas equipment specifying program 43b.

  Next, in the gas leak alarm system 100 of the present embodiment, when an abnormal use state of the gas device 6 is specified, the gas leak alarm device 1 can output an alarm for the abnormal use state. As the abnormal use state, the first abnormal use in which the gas device 6 corresponding to the human sensor 34 is switched from the gas non-consumption state to the gas consumption state in a state where the human sensor 34 has not detected a person. The state and the state during which the gas sensor 6 corresponding to the human sensor 34 is consuming the gas (gas consumption state) in a state where the human sensor 34 has not detected a person are a predetermined threshold time. (Continuous use allowable time) The second abnormal use state continued for T1 is defined. This second abnormal use state is a state in which the gas is forgotten to be turned off. The gas consumption status of each gas device 6 can be individually grasped by the individual flow rate integration program 43a continuously executed in the gas meter 4. The alarm output for the first and second abnormal use states is made by the CPU 11 executing the abnormal use state alarm program 13a stored in the ROM 13 of the gas leak alarm 1. Note that, by executing the abnormal use state alarm program 13a, the abnormal use state determination unit and the abnormal use state alarm output unit in the present invention function.

  FIG. 5 is a flowchart showing the flow of the abnormal use state alarm program 13a. When the abnormal use state alarm program 13a is executed, first, in S200, it is determined whether or not the gas device 6 corresponding to the gas leak alarm 1 itself that executes the program 13a is in a gas consumption state. Specifically, in the gas meter 4, integrated information indicating that the gas flow rate related to the gas device 6 is being integrated is received from the gas meter 4, and the determination is made based on the integrated information. In the gas meter 4, the individual flow rate integration program 43 a is continuously executed and the integration process of each gas device 6 is executed. Therefore, in the individual flow rate integration program 43 a, the gas device 6 being subjected to integration (gas consumption). Is determined to be periodically transmitted to the corresponding gas leak alarm 1, and the gas leak alarm is received by the gas leak alarm. In S200, when the gas leak alarm 1 has received the integrated information, that is, when the gas device 6 corresponding to the gas leak alarm 1 is in a gas consumption state, the process proceeds to S201, and the gas leak alarm The detection result is acquired from the human sensor 34 provided in 1 itself. In S202, it is determined whether or not a person is detected in the detection result of the human sensor 34.

  In S202, when it is determined that a person is detected in the detection result of S201, the process proceeds to S203. In S203, when the human sensor 34 that has been in the detection state in S202 becomes an undetected state, the process proceeds to S204. In S204, the timer 16 is activated and starts counting. In S205, it is determined whether or not the time measured by the timer 16 has exceeded a predetermined threshold time T1. Specifically, the determination is made based on whether or not the count value counted by the timer 16 is equal to or greater than a predetermined set value.

  In S205, if the elapsed time is less than the predetermined threshold time T1, the process proceeds to S208. In S208, the current detection result of the human sensor 34 that was in the undetected state in S203 is acquired, and if it is in the detected state again, the process proceeds to S209, the timer 16 is reset, and the program 13a is terminated. On the other hand, when the detection result of the human sensor 34 acquired in S208 is an undetected state, the process returns to S204 and the counting by the timer 16 is continued.

  In S205, when the elapsed time after the activation of the timer 16 becomes equal to or longer than a predetermined threshold time T1, the process proceeds to S206. In S206, similarly to S200, it is determined whether or not the gas device 6 corresponding to the gas leak alarm 1 itself that executes the program 13a is continuously in the gas consumption state. If the gas is not consumed, the process proceeds to S209, the timer 16 is reset, and the program 13a is terminated. On the other hand, if the gas consumption state continues, the process proceeds to S207, where the control unit 10 and the display control unit 22 and the alarm output the alarm corresponding to the second abnormal use state (warning notification 2: forgetting to turn off alarm output). A warning output command is transmitted to the sound output control unit 23, and a predetermined warning output related to the first abnormal use state is executed from the display unit 32 and the warning sound output unit 33 which are warning output units. Then, the program 13a is terminated. Note that the program 13a repeatedly executes the above processing at predetermined time intervals.

  Return to S202. If it is determined in S202 that no person has been detected, the process proceeds to S210. In S210, it is determined whether or not the timer 16 started in S204 is counting and whether or not the alarm output in the second abnormal use state executed in S207 is being executed. If either of them is being executed, the program 13a is terminated. When neither of them is executed, the process proceeds to S211 and the control unit 10 and the display control unit 22 so as to output an alarm (warning notification 1: natural leak alarm output) corresponding to the first abnormal use state. A warning output command is transmitted to the warning sound output control unit 23, and a predetermined warning output related to the first abnormal use state is executed from the display unit 32 and the warning sound output unit 33 which are warning output units. Then, the program 13a is terminated.

  When an alarm is output by the abnormal use state alarm program 13a, the CPU 11 of the gas leak alarm 1 that has executed the program 13a executes an alarm output stop program 13b stored in the ROM 13. Thereby, in the state where the gas concentration abnormality alarm or the abnormal use state alarm is output, when the human sensor 34 detects a person, after a predetermined threshold time (alarm output duration) T2 has elapsed. The output of the abnormal use state alarm can be stopped. The abnormal use state alarm stop means of the present invention functions by the CPU 11 executing the alarm output stop program 13b.

  FIG. 6 is a flowchart showing the flow of the alarm output stop program 13b. When the alarm output stop program 13b is executed, first, in S30, it is determined whether or not the gas leak alarm 1 that executes the program 13b itself is outputting an alarm. If the alarm is not being output, the program 13b is terminated. If the alarm is being output, the process proceeds to S31. In S31, it is determined whether or not the human sensor 34 provided in the gas leak alarm device 1 has detected a person. If not detected, the program 13b is terminated and alarm output is continued. If it is in the detection state, the process proceeds to S32, where the timer 16 is activated to determine whether or not a predetermined threshold time T2 has elapsed. Specifically, it is determined whether or not the count value counted by the timer 16 is equal to or greater than a predetermined set value. And S32 is repeated until threshold time T2 passes. When the threshold time T2 elapses, the process proceeds to S33, the currently output alarm is stopped, and the program 13b is terminated.

  In addition, after the alarm output 1 and the alarm output 2 are output, if the respective threshold values (continuous use prohibition time) T3 are continuously output after the alarm output 1 and the alarm output 2 are output, the shut-off valve is based on the elapsed time. A valve closing process is executed in which the gas supply to all the gas appliances 6 is shut off by shifting 63 to the valve closed state. The threshold time T3 is stored in the ROM 43, and the controller (valve drive control means) 40 starts counting by the timer 46 based on the fact that the use of the gas equipment is specified, and shuts off when the threshold time T3 elapses. A valve closing command signal is outputted to the valve control unit 53 to the shut-off valve control unit 53, and the shut-off valve 63 is shifted to the valve closed state. Thereby, not only alarm output but gas supply can be stopped forcibly.

  As mentioned above, although one Embodiment of this invention was described, this invention is not limited to the said embodiment, A various deformation | transformation is possible in the range which does not deviate from the main point of this invention.

  For example, in the gas meter 4, the threshold time T <b> 1 set for outputting an abnormal use state alarm can be set to a different value depending on the gas device 6. In this case, the gas leak alarm device 1 stores the threshold time T1 corresponding to the corresponding gas device 6 (for example, stored in the ROM 13), and when starting the timer 16 in S204 of the flowchart of FIG. The control unit 49 is configured to read and set the threshold time T1.

  Moreover, in the said embodiment, the gas meter 4 detects the use condition (the presence or absence of a gas consumption state) of each gas apparatus 6, and uses the usage information signal (integrated information in the said embodiment) according to the detection result for each gas. The gas leak alarm device 1 that has executed the transmission process to be transmitted to the leak alarm device 1 and has received the use state signal is configured to be able to grasp the use status of the gas device 6 corresponding to itself. For this reason, in S200 and S206 of the abnormal use state alarm program 13a in the above embodiment, the gas leak alarm device 1 determines the use status of the corresponding gas device 6 based on the use information signal. However, in the gas meter 4 of the above embodiment, the use status of the gas device 6 corresponding to itself may be grasped based on the execution result by the in-use gas device identification program 43b. The in-use gas device identification program 43b stores the use status of each gas device 6 in the use determination flag of the RAM 42, so that the gas leak alarm 1 acquires the value of the use determination flag by communicating with the gas meter 4. You may comprise.

  Moreover, in the said embodiment, although the abnormal use condition alarm program 13a and the alarm output stop program 13b are performed in the gas leak alarm 1, this program 13a, 13b is comprised so that it may be performed in the gas meter 4. May be. In the case of this configuration, the programs 13a and 13b are stored in the ROM 43, and in these programs 13a and 13b, the use state (presence / absence of gas consumption state) of each gas device 6 is determined. The detection result of the human sensor 34 corresponding to each gas appliance 6 is obtained by communication from the gas leak alarm 1, and processing by the timer 16 of the gas leak alarm 1 is performed. The operation is performed by the timer 46 of the gas meter 4. Further, the alarm notification (alarm output) is transmitted from the gas meter 4 to the corresponding gas leak alarm device 1 to cause the gas leak alarm device 1 to execute the alarm output command. By transmitting an alarm output stop command to the corresponding gas leak alarm device 1, the gas leak alarm device 1 is configured to stop the alarm output.

  Also in this configuration, the threshold time T <b> 1 set for outputting the abnormal use state alarm can be set to a different value depending on the gas device 6. Further, the threshold time T1 may be set dynamically according to the gas flow rate detected by the gas meter 4 instead of being fixedly set for each gas device 6. Specifically, it may be set based on the flow rate classification of the gas flow rate detected by the gas meter 4.

Schematic which shows one Embodiment of the gas leak warning system of this invention. The block diagram which shows the electric constitution of the gas leak alarm which comprises the gas leak alarm system of FIG. The block diagram which shows the electric constitution of the gas meter which comprises the gas leak warning system of FIG. The flowchart explaining the flow of in-use gas equipment specific processing. The flowchart explaining the flow of an abnormal use condition alarm process. The flowchart explaining the flow of a warning output stop process.

Explanation of symbols

DESCRIPTION OF SYMBOLS 100 Gas leak alarm system 1 (1a, 1b) Gas leak alarm 1A, 1B Alarm main body 10 Control part 31 Gas sensor 32 Display part 33 Alarm sound output part 34 Human sensor (person detection means)
25 Gas meter I / F
4 Gas meter 40 Control unit 61 Gas flow sensor 62 Meter display unit 63 Shut-off valve 55 Gas leak alarm I / F
63 Shut-off valve 6 (6a, 6b) Gas equipment

Claims (10)

Gas having gas concentration abnormality alarm output means for detecting a gas concentration in a room where a gas apparatus is installed with a gas sensor and outputting a gas concentration abnormality alarm when the gas concentration exceeds a predetermined threshold level A leak alarm,
A gas meter for detecting a gas flow rate supplied to the gas device;
Gas consumption state detection means for detecting whether or not the gas device is in a gas consumption state based on the gas flow rate detected by the gas meter;
A person detecting means for detecting a person existing around the gas appliance;
Based on the detection states of the gas consumption state detection means and the person detection means, the gas equipment is in the gas consumption state, and a person is not detected around the gas equipment. An abnormal use state determination means for determining whether or not the device is in a predetermined abnormal use state;
An abnormal use state alarm output means for outputting an abnormal use state alarm for notifying that the gas leak alarm device is in the abnormal use state when it is determined to be in the abnormal use state;
A gas leak alarm system characterized by comprising:   The abnormal use state determination means is in a state where the person detection means is not detecting the person, and the detection state by the gas consumption state detection means is switched from the gas non-consumption state to the gas consumption state. The gas leak alarm system according to claim 1, wherein it is determined that the abnormal use state is established.   The abnormal use state determination unit is configured to detect the gas consumption state detected by the gas consumption state detection unit in a state in which the person detection unit does not detect the person, and when the gas consumption state continues for a predetermined threshold time, The gas leak alarm system according to claim 1 or 2, wherein it is determined that an abnormal use state is established.   An abnormality that stops the output of the abnormal use state alarm when a predetermined continuous output period has elapsed when the person detecting means detects the person in a state where the abnormal use state alarm is being output. The gas leak alarm system according to any one of claims 1 to 3, further comprising a use state alarm stop unit. A plurality of the gas appliances are installed;
The human detection means is provided corresponding to the plurality of gas appliances,
The gas meter pre-registers the plurality of gas devices, and has individual flow rate detection means for detecting the consumed gas flow rate for each of the registered gas devices,
The gas consumption state determination means detects whether or not the gas consumption state for each gas device based on the gas flow rate for each gas device detected by the gas meter,
The abnormal use state determination means is provided on the condition that the gas device determined to be in the gas consumption state by the gas consumption state determination means and the person detection means not detecting a person correspond to each other. The gas leak alarm system according to any one of claims 1 to 4, wherein it is determined whether or not the gas appliance is in a predetermined abnormal use state.   The abnormal use state alarm output means is provided corresponding to the plurality of gas devices, and outputs the abnormal use state alarm when it is determined that the corresponding gas device is in the abnormal use state. 5. The gas leak alarm system according to 5.   The gas leak alarm system according to any one of claims 1 to 6, wherein the gas concentration abnormality alarm output unit and the abnormal use state alarm output unit are combined in a common alarm output unit.   The gas leak alarm system according to claim 7, wherein the gas leak alarm has an alarm main body in which the alarm output unit, the gas sensor, and the human detection means are integrally incorporated in a casing. Comprising the requirements of claim 3;
The said abnormal use state determination means is provided with the threshold time change means which sets the said different threshold time according to the said gas equipment which is the object which determines the said abnormal use state. Gas leak alarm system as described in.   The gas leak alarm system according to any one of claims 1 to 9, wherein the gas meter detects the flow rate of the gas supplied to the gas device as an integrated value.

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