JP7089393B2 - Alarm - Google Patents

Description

The present invention relates to an alarm device.

For example, Patent Document 1 discloses a fire alarm with an emergency light function that provides emergency lighting in the event of a power failure. This fire alarm monitors the voltage of the internal power supply unit, the emergency lighting unit, the line power supply unit connected to the commercial power supply to supply power to each unit, and the line power supply unit, and the voltage becomes lower than the reference voltage. It is equipped with a lighting control unit that sometimes supplies internal power to the emergency lighting unit.

For example, Patent Document 2 describes a technique in which an alarm device provided with a main power source and a backup power source does not supply power to a gas leak detecting means having a large power consumption when the backup power source is used as a power source instead of the main power source. Is disclosed. Further, for example, Patent Document 3 discloses a technique for switching to battery drive in the event of a power failure in a gas leak alarm having a battery terminal portion for connecting a battery. Further, there is disclosed a technique for notifying a gas user that a gas leak alarm is out of the outlet by outputting and displaying a voice different from the gas leak when the battery is exhausted.

Further, for example, in Patent Document 4, in a gas alarm device including a long-life backup battery and a main power supply battery that is normally used, when the main power supply battery is switched to the backup battery, the battery is replaced by voice or the like. The technology to issue the message of is disclosed. Further, according to Patent Document 5, in a battery-powered alarm device, when the voltage of the battery monitored by the voltage monitoring means is lowered to a predetermined voltage or less, the confirmation request receiving means receives a confirmation request from the user. , A technique for outputting a voice message including a content prompting battery replacement is disclosed. Further, Patent Document 6 discloses a technique for notifying an abnormality of a storage battery by issuing an alarm at the same time as blinking an indicator lamp by an auxiliary power source when the storage battery is insufficiently charged or has a deteriorated function, and promoting replacement or inspection of the storage battery. Has been done.

Japanese Unexamined Patent Publication No. 2005-293308 Japanese Unexamined Patent Publication No. 2005-108109 Jitsukaihei 5-79695 Gazette Japanese Unexamined Patent Publication No. 2000-22655 Japanese Patent No. 3895646 Jikkenhei 5-88160 Gazette

However, although general users are aware of the basic functions of alarms, such as the generation of alarms when an abnormality occurs, they are not familiar with all the functions. Therefore, even if the emergency light of the alarm is turned on after the power supply from the external power supply is cut off, the user may feel uncomfortable because he / she does not understand why the alarm is turned on.

The present invention has been made in view of such circumstances, and an object of the present invention is to provide an alarm device having an emergency light function with less discomfort to the user.

In order to solve such a problem, the present invention provides an alarm device that issues an alarm when it is determined that an abnormal state has occurred in the monitoring area based on a signal from the monitoring sensor. This alarm has a power supply unit that supplies power supplied from an external power source, a standby power supply unit that can supply power, a light emitting unit that lights up when the power is supplied, and the power supply from the external power supply is cut off. When the power failure detection unit detects that the power is cut off and the power supply is cut off from the external power supply, the power from the standby power supply unit turns on the light emitting unit to operate the emergency light function. It has a power failure processing unit and a power failure processing unit. In this case, after the power failure detection unit detects that the power supply from the external power supply is cut off, the power failure processing unit turns on the light emitting unit by the power from the standby power supply unit to operate the emergency light function, and the backup power supply unit operates. The power is not supplied to the monitoring sensor, and the monitoring sensor outputs a voice indicating that the gas leak cannot be detected .

Further, in the present invention, it is preferable that the power failure processing unit notifies that the power supply from the external power source has been restored when the power failure detection unit detects the restoration of the power supply from the external power source.

Further, in the present invention, it is preferable that the power failure processing unit notifies that the light emitting unit is about to turn off when the voltage of the backup power supply unit reaches the lower limit determination voltage for determining the voltage drop.

Further, in the present invention, the light emitting unit may be configured so that the brightness at the time of lighting can be switched among a plurality of brightness levels. In this case, it is preferable that the power failure processing unit switches the brightness level of the light emitting unit that is lit by the electric power from the backup power supply unit when the switch for operating the alarm device is operated.

Further, in the present invention, it is preferable that the power failure processing unit lights at the highest brightness level among the switchable brightness levels when the light emitting unit is turned on by the electric power from the backup power supply unit.

Further, it is preferable that the present invention further has an illuminance sensor that detects the brightness around the alarm. In this case, when the power supply from the external power supply is cut off and the surroundings are determined to be dark according to the detection result of the illuminance sensor, the power failure processing unit lights the light emitting unit with the power from the backup power supply unit. Is preferable.

Further, in the present invention, the monitoring sensor is a low power consumption type sensor that can be driven for a certain period by power supply from the standby power supply unit, and when the power supply from the external power supply is cut off, the standby power supply unit. It is preferable that the power from the power supply is also supplied to the monitoring sensor.

Further, in the present invention, the power failure processing unit determines whether or not the backup power supply unit has a dead battery in addition to the initial inspection performed when the power is turned on, and if the backup power supply unit has a dead battery. It is preferable to notify that the battery is dead.

Further, in the present invention, in the power failure processing unit, when the abnormality detection by the monitoring sensor is effective, the backup power supply unit is out of battery in addition to the functional inspection performed by operating the switch for operating the alarm. It is preferable to determine whether or not the battery is dead, and if the backup power supply unit is out of battery, notify the dead battery.

The present invention also provides an alarm that issues an alarm when it is determined that an abnormal state has occurred in the monitoring area based on a signal from the monitoring sensor. This alarm has a light emitting unit and a lighting processing unit that turns on the light emitting unit when the abnormality detection by the monitoring sensor is effective and turns off the light emitting unit when the abnormality detection by the monitoring sensor is invalid. ing.

According to the present invention, the alarm can be turned on as an emergency light, and the lighting of the alarm can be linked to the emergency light function, so that the user can understand why the alarm is turned on. can. Therefore, it is possible to provide an alarm device having an emergency light function that does not cause discomfort to the user.

A block diagram schematically showing the configuration of the alarm device according to the first embodiment. Front view schematically showing the configuration of the alarm device according to the first embodiment. Side view schematically showing the configuration of the alarm device according to the first embodiment. Explanatory drawing explaining the emergency light function of the alarm device which concerns on 1st Embodiment A block diagram schematically showing the configuration of the alarm device according to the second embodiment. A flowchart showing the operation of the power failure processing unit according to the second embodiment. A flowchart showing the operation of the power failure processing unit according to the third embodiment.

(First Embodiment)
FIG. 1 is a block diagram schematically showing the configuration of the alarm device 1 according to the present embodiment. 2 is a front view schematically showing the configuration of the alarm device 1 according to the present embodiment, and FIG. 3 is a side view schematically showing the configuration of the alarm device 1 according to the present embodiment. The alarm device 1 according to the present embodiment issues an alarm when it is determined that an abnormal state has occurred in the monitoring area based on the signal from the monitoring sensor. The alarm device 1 according to the present embodiment is a gas alarm device for LP gas or city gas, and is installed, for example, on a wall surface W or the like in a room.

The alarm device 1 includes a gas sensor 2 and a microcomputer (hereinafter referred to as a microcomputer) 3 to which a detection result from the gas sensor 2 is supplied. Further, the alarm device 1 operates the plurality of LEDs 4, the speaker 5, the LED drive unit 6 for driving the plurality of LEDs 4, the speaker drive unit 7 for driving the speaker 5, and the alarm device 1. It is equipped with a switch 8 and.

The gas sensor 2 is a sensor that detects gas, for example, a contact combustion type gas sensor. The gas sensor 2 detects the concentration of the gas contained in the atmosphere, and outputs a detection signal corresponding to the concentration to the microcomputer 3. As the gas sensor 2, a well-known gas sensor such as a semiconductor gas sensor can also be used.

The microcomputer 3 is a microcomputer mainly composed of a CPU, a ROM, a RAM, and an I / O interface. When this is functionally grasped, the microcomputer 3 includes a detection processing unit 3A, an alarm processing unit 3B, and a power failure processing unit 3C (the power failure processing unit 3C will be described later).

The detection result of the gas sensor 2 is supplied to the detection processing unit 3A. The detection processing unit 3A detects a gas leak from the detection result of the gas sensor 2.

The alarm processing unit 3B controls the LED drive unit 6 and the speaker drive unit 7. When the detection processing unit 3A detects a gas leak, the alarm processing unit 3B controls the LED drive unit 6 to turn on the LED 4 (including blinking that repeats turning on and off). The lighting of the LED 4 corresponds to a display alarm that notifies the surroundings of a gas leak. Further, when the detection processing unit 3A detects a gas leak, the alarm processing unit 3B controls the speaker drive unit 7 to output sound or voice from the speaker 5. The operation of the speaker 5 corresponds to a voice alarm for notifying the surroundings of a gas leak.

The plurality of LEDs 4 are light emitting units that are turned on by being supplied with electric power and emit light from the alarm device 1 to the surroundings thereof, and are mainly for performing a display alarm. The plurality of LEDs 4 are composed of three types of LEDs 4R, 4G, and 4W including, for example, red, green, and white. Of the plurality of LEDs 4R, 4G, and 4W, the red LED 4R is turned on when a display alarm is generated. Further, the green LED 4G is turned on to notify the energized state of the alarm device 1 when power is supplied from the external power source 100. On the other hand, the white LED 4W is turned on as an emergency light that illuminates the surroundings of the alarm device 1 when the power supply from the external power source 100 is cut off. Since it is necessary to illuminate the surroundings brightly, a plurality of white LEDs 4W may be provided. Alternatively, one high-luminance type element (LED) may be provided.

Further, the alarm device 1 has a plug 9, a power supply unit 10, a backup power supply unit 11, a power failure detection unit 12, and an illuminance sensor 13.

The plug 9 electrically connects an external power source 100, for example, a commercial AC power source, to the alarm device 1. The plug 9 can be inserted and removed from the plug receiver 101 installed on the wall surface W and electrically connected to the external power source 100.

The power supply unit 10 is connected to the external power supply 100 via the plug 9. The power supply unit 10 supplies the electric power supplied from the external power supply 100 to each unit of the alarm device 1. Further, the power supply unit 10 also has a function of converting AC power from the external power source 100 into direct current.

The backup power supply unit 11 is a power source for supplying the self-owned power. As the backup power supply unit 11, a secondary battery such as a battery, a primary battery, or the like can be used.

The power failure detection unit 12 detects that the power supply from the external power supply 100 has been cut off. A situation in which the power supply from the external power source 100 is cut off mainly includes a power outage. As the power failure detection unit 12, for example, a transistor, a photocoupler, a relay, or the like can be used. The power failure detection unit 12 is connected to the input port of the microcomputer 3 and outputs a status signal according to the detection result. The microcomputer 3 can determine whether or not the power supply from the external power supply 100 is cut off according to the state change (High state, Low state) of the input port.

When there is power supply from the external power supply 100, the power to each part of the alarm device 1 is supplied from the power supply unit 10 (external power supply 100). On the other hand, when the power supply from the external power source 100 is cut off, the power supply of the alarm device 1 is switched by the power failure detection unit 12. By this switching, the electric power to each part of the alarm device 1 is supplied from the backup power supply part 11. When the power supply from the external power supply 100 is restored, the power failure detection unit 12 switches the power supply of the alarm device 1. By this switching, the electric power to each part of the alarm device 1 is supplied from the power supply part 10.

Since the power possessed by the backup power supply unit 11 is finite, the power supply destination is limited when the power is supplied from the backup power supply unit 11. Specifically, the electric power is limitedly supplied only to the place necessary for realizing the emergency light function described later, and the gas sensor 2 having a large power consumption is not supplied with the electric power.

The illuminance sensor 13 is a sensor that detects brightness. The illuminance sensor 13 detects the brightness around the alarm device 1 and outputs a detection signal corresponding to the brightness to the microcomputer 3.

The above-mentioned elements constituting the alarm device 1 are mounted on a substrate (not shown) and housed in the case body 20. The case body 20 is a housing for accommodating various parts constituting the alarm device 1, and is formed of, for example, synthetic resin. When the alarm device 1 is installed on the wall surface W, the back surface 20b of the case body 20 is attached so as to face the wall surface W.

A speaker opening 21, an operation unit 22, a display window unit 23, a gas detection unit 24, and a detection window unit 25 are provided on the front surface 20a of the case body 20.

The speaker opening 21 is an opening that outputs the sound or voice from the speaker 5 to the outside of the case body 20. The speaker opening 21 is composed of, for example, a plurality of small holes penetrating the case body 20, and is formed at a front position of the speaker 5 housed in the case body 20.

The operation unit 22 operates the switch 8 through a pressing operation by the user. Specifically, the operation unit 22 is formed at a position in front of the switch 8 housed in the case body 20, and is configured so that a required range can be displaced. The user can operate the switch 8 by pressing the operation unit 22 and displacing the operation unit 22.

The display window unit 23 is a portion that outputs light from the plurality of LEDs 4 to the outside of the case body 20. The display window portion 23 is formed of an opening obtained by cutting out a part of the case main body 20 into a required shape, and is formed at a front position of a plurality of LEDs 4 housed in the case main body 20. A transparent or translucent plate that closes the opening is arranged in the opening forming the display window portion 23.

The gas detection unit 24 is arranged at the upper right of the front surface 20a of the case body 20. The gas detection unit 24 is composed of a plurality of slits penetrating the inside and outside of the case body 20, and is an opening for allowing the surrounding atmosphere to flow into the inside (sensor chamber) of the alarm device 1. The gas detection unit 24 is formed at a position corresponding to a sensor chamber, which is a space defined in the case body 20 so as to include the gas sensor 2.

The detection window portion 25 is a portion that guides the ambient light of the alarm device 1 to the illuminance sensor 13 housed in the case main body 20. The detection window portion 25 is formed of an opening obtained by cutting out a part of the case main body 20 into a required shape, and is formed at a front position of the illuminance sensor 13 housed in the case main body 20. A transparent or translucent plate that closes the opening is arranged in the opening forming the detection window portion 25.

Further, the above-mentioned plug 9 is provided on the back surface 20b of the case body 20. The plug 9 is a cordless type that is integrally attached to the case body 20. The insertion plug 9 is configured to be retractable with respect to the case body 20 so as to protrude from the back surface 20b of the case body 20 only when it is inserted into the plug receiver 101 of the wall surface W.

Hereinafter, the emergency light function of the alarm device 1, which is one of the features of the present embodiment, will be described. The emergency light function of the alarm device 1 is executed by the power failure processing unit 3C of the microcomputer 3. Here, FIG. 4 is an explanatory diagram illustrating the emergency light function of the alarm device 1 according to the present embodiment.

First, when power is supplied from the external power source 100, the power failure processing unit 3C controls the LED drive unit 6 to light the green LED 4G in order to notify the energization state of the alarm device 1.

When the power supply from the external power source 100 is cut off due to the occurrence of a power failure, the power failure detection unit 12 switches the power supply. By this switching, electric power is supplied from the backup power supply unit 11 to each unit of the alarm device 1.

By monitoring the state of the input port, the power failure processing unit 3C can determine that the power supply from the external power source 100 has been cut off from the state change. When the power failure processing unit 3C determines that the power supply from the external power source 100 is cut off, the power failure processing unit 3C controls the LED drive unit 6 to turn off the green LED 4G and turn on the white LED 4W. As described above, when the power supply from the external power supply 100 is cut off, the power supply of the alarm device 1 is switched from the power supply unit 10 (external power supply 100) to the backup power supply unit 11, so that the white LED 4W is reserved. It lights up by the electric power from the power supply unit 11. That is, the emergency light function is operated by lighting the white LED 4W.

Further, in the present embodiment, the power failure processing unit 3C notifies that the power supply from the external power source 100 is cut off when the white LED 4W is turned on. The method of notification is voice notification by the speaker 5, and for example, a voice such as "a power failure has occurred" is output.

Further, when the power supply of the alarm device 1 is switched to the backup power supply unit 11, the power supply to the gas sensor 2 is not supplied. Therefore, the gas sensor 2 (detection processing unit 3A) does not detect the gas leak. Therefore, the power failure processing unit 3C may further notify that the gas leak detection by the gas sensor 2 is invalid. The method of notification is voice notification by the speaker 5, for example, a voice such as "A gas leak cannot be detected because a power failure has occurred" is output.

On the other hand, when the power supply from the external power supply 100 is restored, the power supply of the alarm device 1 is switched to the power supply unit 10 (external power supply 100) by the power failure detection unit 12. Further, the power failure processing unit 3C can determine that the power supply from the external power source 100 has been restored from the state change by monitoring the state of the input port. When the power supply from the external power source 100 is restored, the power failure processing unit 3C notifies that the power supply from the external power source 100 has been restored. The method of notification is voice notification by the speaker 5, for example, a voice such as "Electricity has been restored" is output. In addition, the power failure processing unit 3C controls the LED drive unit 6 to turn off the white LED 4W and turn on the green LED 4G. This makes it possible to visually recognize the resumption of energization by the external power supply 100.

Further, the power failure processing unit 3C can monitor the voltage of the backup power supply unit 11. Then, the power failure processing unit 3C has a lower limit for determining the voltage drop of the backup power supply unit 11 from the start of the power supply by the standby power supply unit 11 to the restoration of the power supply by the external power supply 100. Judge whether or not the judgment voltage has been reached. When it is determined that the voltage of the backup power supply unit 11 has decreased (that is, when the relationship of the voltage of the backup power supply unit 11 ≤ the lower limit determination voltage is established), the power failure processing unit 3C notifies that the white LED 4W is about to be turned off. .. The method of notification is voice notification by the speaker 5, for example, a voice such as "The lamp of the emergency light will be turned off soon" is output. In addition to the power failure processing unit 3C, the power failure detection unit 12 may determine the voltage drop of the backup power supply unit 11 and notify the power failure processing unit 3C of the determination result.

Further, the emergency light function of the alarm device 1 can be provided with the following additional functions in addition to the above-mentioned basic functions.

First, in the alarm device 1 of the present embodiment, the plurality of LEDs 4 can switch the brightness level in multiple stages according to the drive current from the LED drive unit 6. In this case, the power failure processing unit 3C lights the white LED 4W at the highest brightness level (brightest level) among the switchable brightness levels when the white LED 4W is turned on by the electric power from the backup power supply unit 11. May be good. In the configuration in which a plurality of white LEDs 4W are provided, the brightness level may be adjusted by selecting the white LEDs 4W that supply the drive current while keeping the drive current as it is.

When power is supplied to the alarm device 1 from the external power source 100, the microcomputer 3 (for example, the power failure processing unit 3C) controls the LED drive unit 6 in order to let the user know the energized state of the alarm device 1. Then, the green LED 4G is lit. In the lighting of the green LED 4G indicating the energized state, a level lower than the highest brightness level is selected. Therefore, the white LED 4W as an emergency light is lit in a brighter state than in a normal state, that is, when power is supplied from the external power source 100.

As mentioned above, the initial lighting of the white LED 4W is done at the highest brightness level. Therefore, the power failure processing unit 3C may switch the brightness level of the white LED 4W when the switch 8 is operated while the white LED 4W is lit. Specifically, when the power failure processing unit 3C determines the operation of the switch 8, it controls the LED drive unit 6 to light the white LED 4W at a brightness level one step lower. Further, the power failure processing unit 3C sequentially lowers the brightness level of the white LED 4W each time the switch 8 is operated. Then, when the switch 8 is operated at the lowest brightness level, the brightness level of the white LED 4W is restored to the highest level.

It should be noted that the switching method in which the brightness level is lowered each time the switch 8 is operated has been described. However, the switching of the brightness level may be such that the brightness level is increased each time the switch 8 is operated. Further, the brightness level may be selected according to the operation of the switch 8.

Further, the alarm device 1 according to the present embodiment includes an illuminance sensor 13. Therefore, the power failure processing unit 3C may turn on the white LED 4W when the power supply from the external power source 100 is cut off and the surroundings of the alarm device 1 are determined to be dark. Specifically, when it is determined that the power supply from the external power supply 100 is cut off, the power failure processing unit 3C reads the detection signal from the illuminance sensor 13. Then, the power failure processing unit 3C compares this detection signal with a predetermined determination value for separating light and dark, and determines whether or not the surroundings of the alarm device 1 are dark.

In this case, when the white LED 4W is turned on, it is notified that the power supply from the external power source 100 is cut off. The method of notification is voice notification by the speaker 5, and for example, a voice such as "a power failure has occurred" is output. This allows the user to understand why the emergency light is turned on.

However, when the surroundings of the alarm device 1 are sufficiently bright, the timing at which the power supply from the external power supply 100 is cut off and the timing at which the white LED 4W is turned on are different. In this case, the power failure detection unit 12 may perform a predetermined notification when the interruption of the power supply from the external power source 100 is detected. The method of notification is voice notification by the speaker 5, for example, a voice such as "A power failure has occurred. The emergency light turns on when the surroundings become dark." Is output. As a result, the user can understand that the emergency light is turned on when the surroundings become dark.

As described above, the power failure processing unit 3C according to the present embodiment may notify that the power supply from the external power supply 100 is cut off after the power supply from the external power supply 100 is cut off.

Further, the power failure processing unit 3C according to the present embodiment notifies that the power supply from the external power source 100 is cut off, that is, the factor for operating the emergency light function. However, the mode itself in which the emergency light function operates may be notified, such as "the emergency light has been turned on." That is, the power failure processing unit 3C according to the present embodiment may notify the emergency light function information after the power failure detection unit 12 detects that the power supply from the external power source 100 is cut off. As a result, the lighting of the alarm device 1 and the emergency light function can be linked, so that the user can understand why the alarm device 1 is turned on.

In particular, in the case of notifying the mode itself in which the emergency light function operates, (1) when the white LED 4W is turned on in conjunction with the detection of the interruption of the power supply from the external power supply 100, or (2) the illuminance sensor 13 When is referred to, it is preferable to perform this when it is determined that the surroundings of the alarm device 1 are dark and the white LED 4W is turned on after the interruption of the power supply from the external power source 100 is detected.

As described above, according to the alarm device 1 of the present embodiment, since the backup power supply unit 11 and the power failure detection unit 12 are mounted, the alarm device 1 can have an emergency light function for lighting the LED 4 in an emergency. ..

Further, according to the alarm device 1 of the present embodiment, since the information of the emergency light function is notified, it is possible to determine why the alarm device 1 is turned on. As a result, it is possible to provide an emergency light function with less discomfort to the user.

Further, according to the present embodiment, it is notified that the gas leak detection by the gas sensor 2 is invalid. In order to suppress power consumption, the power of the backup power supply unit 11 is limitedly supplied to those necessary for the emergency light function, and is not supplied to the gas sensor 2. Therefore, the gas leak detection by the gas sensor 2 is not performed. However, when the alarm 1 is lit as an emergency light, the user may have the illusion that the alarm 1 is operating normally and may not notice that the gas leak detection is disabled. There is sex. In this respect, according to the alarm device 1 of the present embodiment, the user can appropriately recognize that the gas leak detection is invalid.

Further, according to the present embodiment, since the restoration of the power supply from the external power source 100 is notified, the user can appropriately recognize that the alarm device 1 is functioning normally.

Further, according to the present embodiment, when it is determined that the voltage of the backup power supply unit 11 has decreased, it is notified that the white LED 4W is about to be turned off. By this notification, the user can be expected to turn off the white LED 4W, so that it is possible to prevent the situation where the white LED 4W is suddenly turned off. This makes it possible to reduce the anxiety of the user due to a power outage.

Further, according to the present embodiment, the brightness of the white LED 4W as an emergency light can be switched by operating the switch 8. As a result, the user can arbitrarily adjust the brightness in an emergency, so that it is possible to provide the alarm device 1 that is easy for the user to use.

Further, according to the present embodiment, since the lighting is performed at the highest brightness level among the switchable brightness levels, it is possible to illuminate the surroundings of the alarm device 1 in a wide range. This makes it possible to obtain emergency light in an appropriate range.

Further, according to the present embodiment, the lighting is performed when the surroundings of the alarm device 1 are dark. As a result, it is possible to suppress a situation in which the alarm device 1 lights up even in a situation where no light is required when the power is cut off, such as during the daytime.

Further, according to the present embodiment, the plug 9 is a cordless type integrated with the case body 20. Therefore, even if the alarm device 1 is removed from the plug receiver 101, the cord does not get in the way and the alarm device 1 can be freely carried. As a result, the alarm device 1 can be effectively used as an emergency light.

Further, the power failure processing unit 3C may perform the following control with reference to the detection signal from the illuminance sensor 13 in a state where the power is supplied from the external power source 100. Specifically, the power failure processing unit 3C controls the LED drive unit 6 from the time when it is determined that the surroundings of the alarm device 1 are dark until it is determined that the surroundings of the alarm device 1 are bright, and the green color is obtained. The white LED 4W may be turned on at the same time as the LED 4G is turned on. That is, when the surroundings of the alarm device 1 are dark, the white LED 4W is turned on as a nightlight that illuminates the surroundings of the alarm device 1. As a result, the alarm device 1 can also function as a nightlight.

Further, when the white LED 4W is turned on as a nightlight, the power failure processing unit 3C may switch the brightness level of the white LED 4W according to the operation of the switch 8. As a result, it is possible to realize a nightlight with an appropriate brightness according to the user's preference.

Further, in the present embodiment, the green LED 4G is turned on when the power is supplied from the external power source 100, and the green LED 4G is turned off when the power supply from the external power source 100 is cut off. Since the power supply to the gas sensor 2 is performed from the external power supply 100, when the power supply from the external power supply 100 is cut off, the power supply to the gas sensor 2 is also stopped. In this case, the gas leak detection by the gas sensor 2 becomes invalid. That is, the power failure processing unit 3C functions as a lighting processing unit that turns on the green LED 4G when the gas leak detection by the gas sensor 2 is effective and turns off the green LED 4G when the gas leak detection by the gas sensor 2 is invalid. I have.

According to this configuration, when the gas leak detection is disabled, the green LED 4G is turned off. Thereby, it is possible to visually determine whether the gas leak detection is invalid or effective from the state of the green LED 4G. In particular, in the present embodiment, the state in which the gas leak detection is invalid and the state in which the power supply from the external power source 100 is cut off are synchronized. Therefore, from the state of the green LED 4G, it is possible to visually determine whether the power is supplied from the external power source 100 or whether the power supply is cut off. This makes it possible to appropriately inform the user of the state of the alarm device 1.

By the way, as described above, the alarm device 1 can be provided with not only an emergency light function but also a nightlight function. If the alarm device 1 has a nightlight function, the white LED 4W lights up according to the brightness of the surroundings even if the power supply from the external power source 100 is not cut off. In this case, when turning on the nightlight, it is conceivable to turn off the green LED 4G and turn on only the white LED 4W. However, when only the white LED 4W is lit, it is difficult for the user to distinguish whether it is lit as an emergency light or as a nightlight. In particular, when the brightness level of the white LED 4W lit as an emergency light and the brightness level of the white LED 4W lit as a nightlight are the same or close to each other, the two cannot be distinguished by the brightness.

In this respect, in the present embodiment, when the gas leak detection is effective, the green LED 4G is turned on. Therefore, when the nightlight is lit, the green LED 4G is lit together with the white LED 4W, while when the emergency light is lit, only the white LED 4W is lit. This makes it possible to easily distinguish from the state of the green LED 4G whether the lighting of the white LED 4W is due to an emergency light or a nightlight. This makes it possible to appropriately inform the user of the state of the alarm device 1.

In this embodiment, not only the alarm device 1 having an emergency light function but also the alarm device 1 having both an emergency light function and a nightlight function has been described. However, if the alarm device 1 switches between valid and invalid gas leak detection by the gas sensor 2, the above-mentioned green LED 4G lighting control method can be widely applied regardless of the presence or absence of the emergency light function or the nightlight function. .. In this case, the function of the lighting processing unit may be realized in the microcomputer 3 mounted on the alarm device 1.

Further, in the present embodiment, the green LED 4G is exemplified as a light emitting unit that notifies that gas leak detection is effective through lighting. However, this light emitting unit is lit in a color other than green if it can be visually distinguished from the light emitting unit (white LED 4W in this embodiment) that illuminates the surroundings of the alarm device 1 as an emergency light or a nightlight. You may.

(Second embodiment)
Hereinafter, the alarm device 1 according to the second embodiment will be described. The difference between the alarm device 1 according to the second embodiment and the alarm device 1 according to the first embodiment is that the power supply from the external power supply 100 is cut off and switched to the backup power supply unit 11. However, it is necessary to continue detecting gas leaks. Here, FIG. 5 is a block diagram schematically showing the configuration of the alarm device 1 according to the second embodiment.

In the present embodiment, the gas sensor 2a is a sensor that detects gas, similar to the gas sensor 2 shown in the first embodiment. As the gas sensor 2a, a sensor that can be driven for a certain period by power supply from the backup power supply unit 11, that is, a sensor with low power consumption is adopted. For example, a MEMS type gas sensor, an electrochemical gas sensor, or the like fall under this category. A MEMS type gas sensor can be used, for example, for methane detection, and an electrochemical gas sensor can be used, for example, for CO detection.

Further, in the present embodiment, when power is supplied from the backup power supply unit 11, the power supply destination from the backup power supply unit 11 includes not only the range necessary for realizing the emergency light function but also the gas sensor 2a. It corresponds to the range EA. Further, the power failure processing unit 3C can switch the power supply destination from the backup power supply unit 11 from the range EA including the gas sensor 2a to the range EB not including the gas sensor 2a by controlling the switching means (not shown). can.

Further, in the present embodiment, the green LED 4G is turned on to notify the energization state of the gas sensor 2 when the gas sensor 2 is supplied with electric power. The power supply to the gas sensor 2 includes both the case where the power is supplied from the external power source 100 and the case where the power is supplied from the backup power supply unit 11. Since the gas sensor 2 performs the gas detection operation in the state where the electric power is supplied, the green LED 4G notifies that the gas leak detection by the gas sensor 2 is effective through its lighting.

Hereinafter, the operation of the alarm device 1 according to the present embodiment, specifically, the operation of the power failure processing unit 3C will be described. Here, FIG. 6 is a flowchart showing the operation of the power failure processing unit 3C according to the present embodiment. The process shown in this flowchart is performed after the alarm device 1 is turned on, that is, after the power is supplied from the external power source 100 (including the restoration of the power supply from the external power source 100).

First, in step S10, the power failure processing unit 3C controls the LED drive unit 6 to light the green LED 4G in order to notify the energization state of the alarm device 1.

In step S11, the power failure processing unit 3C monitors the state of the input port and determines whether or not the power failure detection unit 12 has detected the interruption of the power supply from the external power supply 100. When the interruption of the power supply from the external power source 100 is detected, a positive determination is made in step S11, and the process proceeds to step S12. On the other hand, if the interruption of the power supply from the external power supply 100 is not detected, a negative determination is made in step S11, and the process returns to step S11.

In step S12, the power failure processing unit 3C notifies that the power supply from the external power source 100 has been cut off. The method of notification is voice notification by the speaker 5, and for example, a voice such as "a power failure has occurred" is output.

In step S13, the power failure processing unit 3C reads the detection signal from the illuminance sensor 13. Then, the power failure processing unit 3C compares this detection signal with a predetermined determination value for separating light and dark, and determines whether or not the surroundings of the alarm device 1 are dark. If the surroundings of the alarm device 1 are not dark, a negative determination is made in step S13, and the process proceeds to step S14. On the other hand, when the surroundings of the alarm device 1 are dark, a positive determination is made in step S13, and the process proceeds to step S21.

In step S14, the power failure processing unit 3C determines whether or not the voltage of the backup power supply unit 11 has reached the lower limit determination voltage for determining the voltage drop. When it is determined that the voltage of the backup power supply unit 11 has decreased (that is, when the relationship of the voltage of the backup power supply unit 11 ≤ the lower limit determination voltage is established), a positive determination is made in step S14, and the process proceeds to step S15. On the other hand, if the voltage drop of the backup power supply unit 11 is not determined (that is, the relationship of the voltage of the backup power supply unit 11> the lower limit determination voltage is established), a negative determination is made in step S14, and the process returns to step S14.

In step S15, the power failure processing unit 3C stops the power supply to the gas sensor 2a. Specifically, the power failure processing unit 3C switches the power supply destination from the backup power supply unit 11 to the range EB that does not include the gas sensor 2a.

In step S16, the power failure processing unit 3C notifies that the gas leak detection by the gas sensor 2a is invalid. The method of notification is voice notification by the speaker 5, for example, a voice such as "Gas leak detection has been stopped" is output.

In step S17, the power failure processing unit 3C controls the LED drive unit 6 to turn off the green LED 4G.

In step S18, the power failure processing unit 3C monitors the state of the input port and determines whether or not the power failure detection unit 12 has detected the restoration of the power supply from the external power source 100. When the restoration of the power supply from the external power source 100 is detected, a positive determination is made in step S18, and the process proceeds to step S19. On the other hand, if the restoration of the power supply from the external power source 100 is not detected, a negative determination is made in step S18, and the process returns to step S18.

In step S19, the power failure processing unit 3C notifies that the power supply from the external power source 100 has been restored. The method of notification is voice notification by the speaker 5, for example, a voice such as "Electricity has been restored" is output. Then, when the notification is completed, the process returns to the process of step S10 (RETURN).

On the other hand, in step S21, the power failure processing unit 3C controls the LED drive unit 6 to light the white LED 4W.

In step S22, the power failure processing unit 3C determines whether or not the switch 8 has been operated. When the switch 8 is operated, a positive determination is made in step S22, and the process proceeds to step S23. On the other hand, if the switch 8 is not operated, a negative determination is made in step S22, and the process proceeds to step S24.

In step S23, the power failure processing unit 3C controls the LED drive unit 6 to turn off the white LED 4W.

In step S24, the power failure processing unit 3C determines whether or not the voltage of the backup power supply unit 11 has reached the lower limit determination voltage. If it is determined that the voltage of the backup power supply unit 11 has decreased, an affirmative determination is made in step S24, and the process proceeds to step S25. On the other hand, if the voltage drop of the backup power supply unit 11 is not determined, a negative determination is made in step S24, and the process returns to step S22.

In step S25, the power failure processing unit 3C stops the power supply to the gas sensor 2a. Specifically, the power failure processing unit 3C switches the power supply destination from the backup power supply unit 11 to the range EB that does not include the gas sensor 2a.

In step S26, the power failure processing unit 3C notifies that the gas leak detection by the gas sensor 2a is invalid. The method of notification is voice notification by the speaker 5, for example, a voice such as "Gas leak detection has been stopped" is output.

In step S27, the power failure processing unit 3C controls the LED drive unit 6 to turn off the green LED 4G.

As described above, in the present embodiment, the gas sensor 2a is a low power consumption type sensor that can be driven for a certain period by the power supply from the backup power supply unit 11. When it is detected that the power supply from the external power supply 100 is cut off, the power from the backup power supply unit 11 is supplied to the gas sensor 2a.

In the alarm device 1 driven by the electric power supplied from the external power source 100, a sensor having a large power consumption can be used as the gas sensor 2a. However, since the power of the backup power supply unit 11 is finite, when a sensor having a large power consumption is used, the power supply to the sensor is stopped when the power supply from the external power supply 100 is cut off. There is a need. In this case, by turning off the green LED 4G, it is notified that the gas leak detection is invalid, and then the white LED 4W as an emergency light is turned on. However, if the user does not understand such an operation, since the emergency light of the alarm device 1 is lit, there is a possibility that gas leak detection is naturally effective.

In this respect, according to the present embodiment, since the gas sensor 2a employs a sensor having a small power consumption, the gas sensor 2a can be driven by the electric power supplied from the backup power supply unit 11. As a result, gas leak detection can be performed even during the period when the power is supplied from the backup power supply unit 11. This makes it possible to provide an alarm device 1 that is easy for the user to use.

Further, in the present embodiment, when the power failure processing unit 3C determines that the power supply from the external power source 100 is cut off and the surroundings are dark according to the detection result of the illuminance sensor 13, the standby power supply unit 11 is used. The white LED 4W is turned on by electric power.

According to this configuration, the emergency light function does not work when the surroundings of the alarm device 1 are bright, so that the power of the backup power supply unit 11 can be effectively used. This makes it possible to effectively detect gas leaks when the external power supply 100 is shut off.

Further, in the present embodiment, the power failure processing unit 3C switches the white LED 4W to off when the switch 8 for operating the alarm device 1 is operated after turning on the white LED 4W.

In the present embodiment, the gas leak detection function and the emergency light function may operate in an overlapping manner, but by operating the switch 8, the emergency light function can be disabled at the user's will. .. As a result, gas leak detection can be executed while suppressing the power consumption of the backup power supply unit 11.

Further, in the present embodiment, the power failure processing unit 3C determines whether or not the voltage of the backup power supply unit 11 has reached the lower limit determination voltage for determining the voltage drop. Then, when it is determined that the voltage of the backup power supply unit 11 has decreased (that is, when the relationship of the voltage of the standby power supply unit 11 ≤ the lower limit determination voltage is established), the power failure processing unit 3C stops the power supply to the gas sensor 2a. At the same time, it notifies that the gas leak detection is invalid (specifically, voice notification and turning off the green LED 4G).

With this configuration, it is possible to inform the user that the gas leak detection is not functioning.

Further, in the present embodiment, when power is supplied to the gas sensor 2a from the external power supply 100 or the backup power supply unit 11, the green LED 4G lights up and the power is supplied from the external power supply 100 or the backup power supply unit 11 to the gas sensor 2a. When is shut off, the green LED 4G goes out. When power is not supplied to the gas sensor 2a, the gas leak detection by the gas sensor 2a becomes invalid. That is, the power failure processing unit 3C functions as a lighting processing unit that turns on the green LED 4G when the gas leak detection by the gas sensor 2a is effective and turns off the green LED 4G when the gas leak detection by the gas sensor 2a is invalid. I have.

According to this configuration, when the power supply from the external power source 100 is cut off and the gas leak detection becomes invalid, the green LED 4G is turned off. Therefore, it is possible to visually determine whether the gas leak detection is invalid or effective from the state of the green LED 4G.

(Third embodiment)
Hereinafter, the alarm device 1 according to the third embodiment will be described. The difference between the alarm device 1 according to the third embodiment and the alarm device 1 according to the first embodiment is that the battery of the backup power supply unit 11 is confirmed to be dead. In the following description, it is assumed that the backup power supply unit 11 is a primary battery. The backup power supply unit 11, which is a primary battery, is configured to be replaceable in case the battery runs out.

Further, the alarm device 1 has an inspection function for inspecting the function of the alarm device 1. This inspection function includes an initial inspection and a functional inspection. The initial inspection is executed after the power of the alarm device 1 is turned on, and the functional inspection is triggered by the operation of the switch 8 during the execution of gas leak detection. Is executed as. The inspection function checks whether the LED drive unit 6 and the speaker drive unit 7 operate normally, and actually drives the speaker 5 through the speaker drive unit 7 or lights a plurality of LEDs 4 through the LED drive unit 6. Let me do it. This inspection function is executed by the alarm processing unit 3B.

FIG. 7 is a flowchart showing the operation of the power failure processing unit 3C according to the present embodiment. The process shown in this flowchart is performed after the alarm device 1 is turned on, that is, after the power is supplied from the external power source 100 (including the restoration of the power supply from the external power source 100).

First, in step S30, the power failure processing unit 3C controls the LED drive unit 6 to light the green LED 4G in order to notify the energization state of the alarm device 1.

In step S31, the power failure processing unit 3C checks the battery during the initial inspection of the alarm processing unit 3B. The battery check monitors the voltage of the backup power supply unit 11 and determines whether or not the voltage of the backup power supply unit 11 has reached the battery exhaustion voltage for determining the battery exhaustion.

In step S32, the power failure processing unit 3C determines whether or not the standby power supply unit 11, which is the primary battery, is out of battery based on the result of the battery check. When the battery of the backup power supply unit 11 is dead (that is, when the relationship of voltage of the backup power supply unit 11 ≤ battery dead voltage is established), a positive determination is made in step S32, and the process proceeds to step S33. On the other hand, when the backup power supply unit 11 is not out of battery (that is, when the relationship of voltage of standby power supply unit 11> out of battery voltage is established), a negative determination is made in step S32, and the process proceeds to step S34.

In step S33, the power failure processing unit 3C notifies that the battery is dead. The timing of the notification is, for example, after the completion of the initial inspection of the alarm processing unit 3B. The method of notification is voice notification by the speaker 5, for example, a voice such as "Please insert a new battery" is output.

In step S34, the power failure processing unit 3C determines whether or not the switch 8 has been operated for the function check. When the switch 8 is operated after the completion of the initial inspection, that is, during the execution of the gas leak detection, since this corresponds to the operation of the functional inspection, a positive determination is made in step S34, and the process proceeds to step S35. On the other hand, if the switch 8 is not operated, a negative determination is made in step S34, and the process proceeds to step S38.

In step S35, the power failure processing unit 3C checks the battery after performing the functional check of the alarm processing unit 3B. The battery check monitors the voltage of the backup power supply unit 11 and determines whether or not the voltage of the backup power supply unit 11 has reached the battery exhaustion voltage for determining the battery exhaustion.

In step S36, the power failure processing unit 3C determines whether or not the standby power supply unit 11, which is the primary battery, is dead, based on the result of the battery check. When the battery of the backup power supply unit 11 is dead (that is, when the relationship of voltage of the standby power supply unit 11 ≤ battery dead voltage is established), a positive determination is made in step S36, and the process proceeds to step S37. On the other hand, when the backup power supply unit 11 is not out of battery (that is, when the relationship of voltage of standby power supply unit 11> out of battery voltage is established), a negative determination is made in step S36, and the process proceeds to step S38.

In step S37, the power failure processing unit 3C notifies that the battery is dead. The method of notification is voice notification by the speaker 5, for example, a voice such as "Please insert a new battery" is output.

In step S38, the power failure processing unit 3C monitors the state of the input port and determines whether or not the power failure detection unit 12 has detected the interruption of the power supply from the external power supply 100. When the interruption of the power supply from the external power source 100 is detected, a positive determination is made in step S38, and the process proceeds to step S39. On the other hand, if the interruption of the power supply from the external power supply 100 is not detected, a negative determination is made in step S38, and the process returns to step S34.

In step S39, the power failure processing unit 3C notifies that the power supply from the external power source 100 has been cut off. The method of notification is voice notification by the speaker 5, and for example, a voice such as "a power failure has occurred" is output.

In step S40, the power failure processing unit 3C stops the power supply to the gas sensor 2.

In step S41, the power failure processing unit 3C notifies that the gas leak detection by the gas sensor 2 is invalid. The method of notification is voice notification by the speaker 5, for example, a voice such as "Gas leak detection has been stopped" is output.

In step S42, the power failure processing unit 3C controls the LED drive unit 6 to turn off the green LED 4G.

In step S43, the power failure processing unit 3C reads the detection signal from the illuminance sensor 13. Then, the power failure processing unit 3C compares this detection signal with a predetermined determination value for separating light and dark, and determines whether or not the surroundings of the alarm device 1 are dark. If the surroundings of the alarm device 1 are not dark, a negative determination is made in step S43, and the process proceeds to step S45. On the other hand, when the surroundings of the alarm device 1 are dark, a positive determination is made in step S43, and the process proceeds to step S44.

In step S44, the power failure processing unit 3C controls the LED drive unit 6 to light the white LED 4W.

In step S45, the power failure processing unit 3C monitors the state of the input port and determines whether or not the power failure detection unit 12 has detected the restoration of the power supply from the external power source 100. When the restoration of the power supply from the external power source 100 is detected, a positive determination is made in step S45, and the process proceeds to step S46. On the other hand, if the restoration of the power supply from the external power source 100 is not detected, a negative determination is made in step S45, and the process returns to step S45.

In step S46, the power failure processing unit 3C notifies that the power supply from the external power source 100 has been restored. The method of notification is voice notification by the speaker 5, for example, a voice such as "Electricity has been restored" is output. Then, when the notification is completed, the process returns to the process of step S30 (RETURN).

As described above, according to the present embodiment, the power failure processing unit 3C determines whether or not the backup power supply unit 11 is out of battery in addition to the initial inspection performed when the power is turned on, and the backup power supply unit 11 is concerned. If the battery is dead, the battery is dead.

The alarm device 1 according to the present embodiment is driven by the electric power supplied from the external power source 100 in the normal state (when the gas leak detection is executed), but is a backup power source when the external power source 100 is cut off. The emergency light is driven by the unit 11 (primary battery). Since the backup power supply unit 11 and the emergency light function are not the original functions (gas leak detection function) of the alarm device 1, they are designed so as not to affect the gas leak detection function. Therefore, it is not configured to notify the battery exhaustion of the backup power supply unit 11. Therefore, even if the voltage of the backup power supply unit 11 drops, the information cannot be notified to the user, so that the user cannot recognize that the battery is dead. Further, since the backup power supply unit 11 cannot be replaced, there is a possibility that the emergency light function cannot be used when a power failure occurs. Further, even if the configuration is such that the battery exhaustion is notified, if the battery exhaustion notification is performed at normal times, an abnormality occurs in the alarm device 1 even though the gas leak detection function is normal. If this is the case, the user may decide that it is there, which may lead to a report to the gas company.

In this regard, according to the present embodiment, the battery exhaustion is not notified in the normal use state, and the battery exhaustion is determined and the battery exhaustion is notified in addition to the initial inspection performed when the power is turned on. .. As a result, the dead battery can be appropriately notified without misunderstanding that the alarm device 1 is abnormal. As a result, when a power failure occurs, it is possible to suppress a situation in which the emergency light does not turn on due to the battery running out.

Further, in the present embodiment, in the power failure processing unit 3C, the backup power supply unit 11 is out of battery in addition to the functional check performed by operating the switch 8 when the gas leak detection by the gas sensor 2 is effective. It is determined whether or not the battery is present, and if the backup power supply unit 11 is out of battery, the battery is exhausted.

According to this configuration, the dead battery is not notified in the normal use state, but the dead battery is notified when the function is inspected by the switch 8. As a result, it is possible to appropriately notify that the battery is dead without misunderstanding that the alarm device 1 is abnormal. As a result, when a power failure occurs, it is possible to suppress a situation in which the emergency light does not turn on due to the battery running out.

Although the alarm device according to the present embodiment has been described above, it is needless to say that the present invention is not limited to this embodiment and various changes can be made within the scope of the invention.

For example, the alarm may be an alarm for various abnormal states such as a fire and incomplete combustion of a combustion appliance (generation of carbon monoxide (CO)) in addition to an alarm for a gas leak.

Further, in the present embodiment, the microcomputer is operated in order to realize the emergency light function, but all or part of the emergency light function is performed by using a circuit or the like without supplying the power of the backup power supply unit to the microcomputer. It may be realized.

Further, in the present embodiment, the light emitting unit (LED) that gives a display alarm functions as an emergency light, but a dedicated light emitting unit may be mounted. However, by diverting the light emitting part that gives a display alarm as an emergency light, it is possible to reduce the number of parts and the product cost.

In this embodiment, a voice method is exemplified as a method for notifying that the power supply is cut off from the external power source, but other notification methods including a display may be used.

1 Alarm 2,2a Gas sensor (monitoring sensor)
3 Microcomputer 3A Detection processing unit 3B Alarm processing unit 3C Power failure processing unit 4 LED (light emitting unit)
4R red LED (light emitting part)
4G green LED (light emitting part)
4W white LED (light emitting part)
5 Speaker 6 LED drive unit 7 Speaker drive unit 8 Switch 9 Plug-in plug 10 Power supply unit 11 Backup power supply unit 12 Power failure detection unit 13 Illuminance sensor 20 Case body 21 Speaker opening 22 Operation unit 23 Display window unit 24 Gas detection unit 25 Detection Window 100 External power supply 101 Plug receiver W Wall surface

Claims (9)

In an alarm that issues an alarm when it is determined that an abnormal condition has occurred in the monitoring area based on the signal from the monitoring sensor.
The power supply unit that supplies the power supplied from the external power supply, and
A backup power supply that can supply power and
A light emitting part that lights up when power is supplied,
A power failure detection unit that detects that the power supply from the external power supply has been cut off, and
When the power failure detection unit detects that the power supply from the external power supply is cut off, the power failure processing unit operates the emergency light function by lighting the light emitting unit with the power from the backup power supply unit. Have and
After the power failure detection unit detects that the power supply from the external power supply is cut off, the power failure processing unit lights the light emitting unit with the power from the standby power supply unit to operate the emergency light function, and the backup unit operates the emergency light function. The power from the power supply unit is not supplied to the monitoring sensor, and the monitoring sensor outputs a voice indicating that the gas leak cannot be detected.
Alarm. The alarm according to claim 1 , wherein the power failure processing unit notifies that the power supply from the external power source has been restored when the power failure detection unit detects the restoration of the power supply from the external power source. The power failure processing unit according to claim 1 or 2 , wherein when the voltage of the backup power supply unit reaches the lower limit determination voltage for determining a voltage drop, the light emitting unit is about to turn off. Alarm. The light emitting unit is configured so that the brightness at the time of lighting can be switched among a plurality of brightness levels.
7 . Alarm. The alarm according to claim 4 , wherein the power failure processing unit lights up at the highest brightness level among the switchable brightness levels when the light emitting unit is initially turned on by the electric power from the backup power supply unit. vessel. It also has an illuminance sensor that detects the brightness around the alarm.
When the power supply from the external power supply is cut off and the surroundings are determined to be dark according to the detection result of the illuminance sensor, the power failure processing unit lights the light emitting unit with the power from the backup power supply unit. The alarm according to any one of claims 1 to 5 . The monitoring sensor is a low power consumption type sensor that can be driven for a certain period of time by supplying power from the backup power supply unit.
The alarm according to claim 1 , wherein when the power supply from the external power supply is cut off, the power from the backup power supply unit is also supplied to the monitoring sensor. The power failure processing unit determines whether or not the backup power supply unit is out of battery in addition to the initial inspection performed when the power is turned on, and if the backup power supply unit is out of battery, notifies the battery exhaustion. The alarm according to any one of claims 1 to 6 . When the abnormality detection by the monitoring sensor is effective, the power failure processing unit is checked for the function performed by operating the switch for operating the alarm, and whether the backup power supply unit is out of battery. The alarm according to any one of claims 1 to 6 and 8 , which determines whether or not the battery is dead, and notifies the battery of the standby power supply unit when the battery is dead.

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