JP7297384B2 - alarm - Google Patents

Description

The present invention relates to alarms.

Conventionally, a fire alarm with an emergency light function that becomes emergency lighting in the event of a power failure has been disclosed. This fire alarm turns on emergency lighting based on a built-in battery (backup power supply) when power supply from a commercial power supply (external power supply) is cut off. According to this fire alarm, the alarm can be used as an emergency light in the event of a power failure such as a disaster.

JP 2005-293308 A

Here, the alarm device described in Patent Document 1 has an automatic switching circuit that automatically switches the contact to the battery side at the time of power failure without being controlled by a microcomputer. However, when the power supply destination is selected by the control of the microcomputer, the following problems may arise due to the following configuration.

First, an alarm device in which a microcomputer is activated by power from an external power supply is assumed. This alarm device is installed in each home or the like, and when power is supplied from an external power supply, a microcomputer is activated to monitor the occurrence of an abnormal state in the monitoring area. In this monitoring state, the microcomputer determines whether or not the voltage from the external power supply has dropped based on the signal from the power failure detection circuit. When the microcomputer determines that the voltage from the external power supply has dropped, it switches the power supply destination to the standby power supply before the voltage drops to the point where the microcomputer cannot operate itself.

Here, for example, if the emergency light is used for a long period of time during a disaster, the standby power supply may be completely consumed. When the backup power supply is completely consumed, the backup power supply must be replaced (replacement includes the case where the rechargeable backup power supply is taken out, charged, and then re-installed in the alarm). In the state alarm, the microcomputer starts up with power from the external power supply, so even if the backup power supply is replaced, the microcomputer will not start up and the power supply destination will not be switched to the backup power supply, and the emergency light will not turn on. .

SUMMARY OF THE INVENTION The present invention has been made to solve such problems. To provide an alarm capable of

The alarm device of the present invention is an alarm device that includes a standby power supply and issues an alarm when it is determined that an abnormal state has occurred in a monitoring area based on a signal from a monitoring sensor, and lighting means that can be turned on. a microcomputer for judging whether the power supply from an external power supply is interrupted or not, and for lighting the lighting means by the electric power from the backup power supply when it is judged to be the power failure ; a speaker for sounding a power recovery message when power is supplied from an external power supply through the microcomputer, the microcomputer is connected to the standby power supply via a switch that is turned on in an initial state, It can be started by power from both the power supply and the standby power supply, and when it is determined that the power failure state is not detected, the switch is turned off to stop the power supply from the standby power supply , and the power supply is started by the standby power supply. When it is determined that the backup power supply has started the power supply, the power recovery message is prohibited from ringing even when power is supplied from the external power supply after the power failure state.

According to the alarm device of the present invention, the microcomputer is connected to the standby power supply via the switch that is turned on in the initial state, and is activated by power from both the external power supply and the standby power supply in the initial state. When it is determined that the power supply from the power supply is not interrupted, the switch is turned off to stop the power supply from the standby power supply. Therefore, even if the standby power supply is used up and the standby power supply is replaced, the microcomputer is connected to the standby power supply via the switch that is turned on in the initial state, so the standby power supply will start up the microcomputer, and the power failure state will occur. is determined to light the lighting means. Therefore, in a configuration in which the microcomputer selects and controls the power supply destination, the emergency light can be turned on even when the standby power supply is replaced.

1 is a block diagram showing a gas alarm device according to an embodiment of the invention; FIG. 4 is a flow chart showing processing executed by the microcomputer of the gas alarm device according to the present embodiment;

BEST MODE FOR CARRYING OUT THE INVENTION The present invention will be described below along with preferred embodiments. It should be noted that the present invention is not limited to the embodiments described below, and can be modified as appropriate without departing from the gist of the present invention. In addition, in the embodiments shown below, there are places where illustrations and explanations of some configurations are omitted, but the details of the omitted technologies are provided within the scope that does not cause contradiction with the contents explained below. , Needless to say, well-known or well-known techniques are applied as appropriate.

FIG. 1 is a block diagram showing a gas alarm device according to an embodiment of the invention. In the following description, gas alarms are used as an example of alarms, but alarms are not limited to gas alarms, and other types of alarms, such as fire alarms, gas fire alarms, and motion detectors, may be used. There may be.

A gas alarm (alarm device) 1 shown in FIG. An alarm is issued when it is determined that this has occurred.

Such a gas alarm device 1 includes a microcomputer 11, an illuminance sensor 12, an LED driver 13, a plurality of LEDs 14, a speaker driver 15, and a speaker 16. The microcomputer 11 controls the entire gas alarm device 1, and includes a detection processing section 11a and an alarm processing section 11b.

The detection processing unit 11 a detects the gas concentration of the gas to be detected based on the signal from the gas sensor 10 . The detection processing unit 11 a also detects ambient illuminance based on the signal from the illuminance sensor 12 .

The alarm processing unit 11b determines that an abnormal state exists when the detection processing unit 11a detects a gas concentration equal to or higher than a predetermined concentration, and executes alarm processing. At this time, the alarm processing unit 11b drives the LED driving unit 13 and the speaker driving unit 15 to turn on (including blinking) at least one of the plurality of LEDs 14 and output an alarm sound from the speaker 16.

Further, the gas alarm device 1 includes an insertion plug 17 , a power supply section 18 , a power failure detection section 19 , a standby power supply 20 , a booster circuit 21 , a switch 22 and a standby power supply stopping section 23 .

The insertion plug 17 is a connection portion with an external power source EPS, which is a commercial AC power source, and can be inserted into and removed from a plug receptacle PR that is installed on a wall or the like and electrically connected to the external power source EPS.

The power supply unit 18 converts AC power from the external power supply EPS into DC power and regulates the voltage. The power failure detection unit 19 outputs a signal to that effect to the microcomputer 11 when power supply from the external power source EPS is interrupted and a power failure state occurs. Further, the microcomputer 11 includes a power failure determination section 11c. The power failure determination unit 11c determines whether or not there is a current power failure based on a signal from the power failure detection unit 19. FIG.

The standby power supply 20 is a power supply source built into the gas alarm device 1, and can be a primary battery such as a dry battery, for example. A secondary battery may be used as the standby power supply 20 . The booster circuit 21 boosts the backup power supply 20 to a voltage suitable for the operation of the microcomputer 11 .

The switch 22 is interposed between the standby power source 20 and the microcomputer 11. When the switch 22 is on, the power of the standby power source 20 is supplied to the microcomputer 11, and when the switch 22 is off, the power supply is interrupted. be done. The switch 22 is turned on in the initial state, and is composed of, for example, a normally closed switch.

The standby power supply stop unit 23 is controlled by the microcomputer 11, and when the power failure determination unit 11c determines that the power failure state is not detected, that is, when the power supply from the external power source EPS is not cut off, the power supply from the microcomputer 11 is stopped. , the switch 22 is turned off to stop the power supply from the standby power supply 20 . On the other hand, when the power failure judging section 11c judges that there is a power failure, there is no instruction from the microcomputer 11. FIG. Therefore, the standby power supply stopping unit 23 supplies power from the standby power supply 20 to the microcomputer 11 without turning off the switch 22 .

Further, the microcomputer 11 has an emergency light processing section 11d. The emergency light processing unit 11d controls the LED driving unit 13 to control the white LED (lighting) among the plurality of LEDs 14 in a state where the power failure determination unit 11c determines that there is a power failure and power is being supplied from the standby power supply 20. Means) 14W is turned on. This white LED 14W functions as an emergency light.

In addition, the microcomputer 11 detects a power failure state by the power failure determination unit 11c and receives power from the standby power supply 20, and the detection processing unit 11a (excluding detection based on the signal from the illuminance sensor 12). and the execution of processing by the alarm processing unit 11b is stopped. As a result, the power of the standby power supply 20 is not consumed for gas concentration detection and alarm execution, and the usage time as an emergency light is extended.

Additionally, the gas alarm device 1 is provided with an operation switch 24 . The emergency light processing unit 11d turns on or off the white LED 14W when the operation switch 24 is operated while receiving power from the standby power supply 20. FIG. Further, when the illuminance detected by the illuminance sensor 12 is equal to or higher than a predetermined value, the emergency light processing unit 11d executes control to turn off the white LED 14W.

FIG. 2 is a flow chart showing processing executed by the microcomputer 11 of the gas alarm device 1 according to this embodiment. The processing shown in FIG. 2 is started when the microcomputer 11 is activated. The microcomputer 11 is activated by inserting the insertion plug 17 into the plug receiver PR and supplying power from the external power source EPS, or even if power from the external power source EPS is not supplied, the switch 22 is turned on in the initial state. is turned on, power is supplied from the standby power supply 20 .

When the process shown in FIG. 2 is started, the power failure determination unit 11c of the microcomputer 11 determines whether the external power supply EPS is on based on the signal from the power failure detection unit 19 (S1). If the external power supply EPS is not on (S1: NO), that is, if the standby power supply 20 starts the microcomputer 11, the process proceeds to step S8.

On the other hand, if the external power supply EPS is on (S1: YES), the microcomputer 11 stops the supply of the standby power supply 20 (S2). In this process, the microcomputer 11 operates the standby power supply stopping unit 23 to turn off the switch 22 . The microcomputer 11 also turns off the booster circuit 21 in the same manner.

After that, the microcomputer 11 causes the gas alarm device 1 to operate normally (S3). That is, the microcomputer 11 monitors the abnormal state.

Next, the power failure determination unit 11c of the microcomputer 11 determines whether or not a power failure state has occurred based on the signal from the power failure detection unit 19 (S4). When the power failure determination unit 11c determines that the power failure state is not detected (S4: NO), the process proceeds to step S3.

When the power failure determination unit 11c determines that the power failure state exists (S4: YES), the microcomputer 11 cancels the stoppage of the standby power supply 20 (S5). That is, the microcomputer 11 cancels the off command to the standby power supply stopping unit 23 . As a result, the switch 22 is turned on. In addition, the microcomputer 11 cancels the operation stop state of the booster circuit 21 as well.

Next, when the microcomputer 11 receives power supply from the standby power supply 20, it stops the operation as the gas alarm device 1 (S6). At this time, the execution of processing by the detection processing unit 11a (excluding detection based on the signal from the illuminance sensor 12) and the alarm processing unit 11b is stopped.

After that, the microcomputer 11 drives the speaker drive unit 15 to sound a power failure message from the speaker 16 to the effect that the power failure has occurred (S7). Next, the emergency light processing section 11d of the microcomputer 11 operates the gas alarm 1 as an emergency light (S8). In this process, the emergency light processing unit 11d drives the LED driving unit 13 to light the white LED 14W.

Next, the power failure determination unit 11c of the microcomputer 11 determines whether or not the power has been restored from the power failure state based on the signal from the power failure detection unit 19 (S9). When the power failure determination unit 11c determines that the power is not restored (S9: NO), the process proceeds to step S8.

When the power failure determination unit 11c determines that the power is restored (S9: YES), the microcomputer 11 stops the supply of the standby power supply 20 (S10). In this process, the microcomputer 11 operates the standby power supply stopping unit 23 to turn off the switch 22 . The microcomputer 11 also turns off the booster circuit 21 in the same manner.

Next, the microcomputer 11 determines whether the processing shown in FIG. 2 has been started by power from the standby power supply 20 (S11). When the microcomputer 11 determines that the power from the standby power supply 20 has started (S11: YES), the process proceeds to step S3.

On the other hand, if the microcomputer 11 determines that the power from the standby power supply 20 has not started the process (S11: NO), that is, if the process has started with the power from the external power supply EPS, the gas alarm device 1 has the external power supply EPS After the power is supplied from the external power supply EPS, power is supplied again from the external power supply EPS through the power failure state. In this case, the microcomputer 11 drives the speaker drive unit 15 to sound the power recovery message from the speaker 16 (S12). After that, the process moves to step S3.

The processing shown in FIG. 2 continues to be executed until the power from the external power source EPS is not supplied and the power of the standby power source 20 is consumed.

Thus, according to the gas alarm device 1 according to the present embodiment, the microcomputer 11 is connected to the standby power source 20 via the switch 22 that is turned on in the initial state, and the external power source EPS and the standby power source are connected in the initial state. It can be started by power from both power sources 20, and when the power supply from the external power source EPS is not interrupted, the switch 22 is turned off to stop the power supply from the standby power source 20. - 特許庁Therefore, even if the backup power supply 20 is replaced because the backup power supply 20 has been consumed, the microcomputer 11 is connected to the backup power supply 20 via the switch 22 that is turned on in the initial state. , the power failure state is determined and the white LED 14W is turned on. Therefore, in the configuration in which the microcomputer 11 selects and controls the power supply destination, the emergency light can be turned on even when the standby power supply 20 is replaced.

In particular, in Patent Document 1, an automatic switching circuit is provided, and the automatic switching circuit selectively switches the contact between the external power supply side and the standby power supply side. Therefore, when the power failure detection circuit fails, the automatic switching circuit does not operate and the emergency light cannot be used. However, in the gas alarm device 1 according to this embodiment, the switch 22 is turned on in the initial state, and is provided for the standby power source 20. It is not intended to selectively switch between sides. Therefore, the power from the standby power supply 20 is first supplied to the microcomputer 11 irrespective of the result of power failure detection. can.

Further, when the microcomputer 11 determines that the electric power supply from the external power source EPS is cut off, the microcomputer 11 is activated by the power boosted by the booster circuit 21, so that the standby power source 20 is activated by the microcomputer 11. The microcomputer 11 can be appropriately activated even if only insufficient voltage is obtained to operate the microcomputer 11 .

Further, the microcomputer 11 stops the power supply from the standby power supply 20 and stops the operation of the booster circuit 21 when the power supply from the external power supply EPS is not interrupted. Therefore, in the case where the backup power supply 20 provides only an insufficient voltage to operate the microcomputer 11 and includes the booster circuit 21, the operation of the booster circuit 21 can be appropriately stopped.

As described above, the present invention has been described based on the embodiments, but the present invention is not limited to the above embodiments, and may be modified without departing from the scope of the present invention. techniques may be combined. Furthermore, you may combine a well-known or well-known technique in the possible range.

For example, in the above-described embodiment, the gas alarm 1 sounds a message when power is cut off or when power is restored. You may do so.

Furthermore, the gas alarm device 1 according to the present embodiment includes the booster circuit 21 for the standby power supply 20, but the present invention is not limited to this. An available standby power supply 20 may be installed.

1: Gas alarm (alarm)
10: Gas sensor (monitoring sensor)
11: Microcomputer 11a: Detection processing unit 11b: Alarm processing unit 11c: Power failure determination unit 11d: Emergency light processing unit 12: Illuminance sensor 13: LED driving unit 14: Plural LEDs
14W: White LED (illumination means)
15: Speaker drive unit 16: Speaker 17: Insertion plug 18: Power supply unit 19: Power failure detection unit 20: Standby power supply 21: Booster circuit 22: Switch 23: Standby power supply stop unit 24: Operation switch EPS: External power supply PR: Plug received

Claims (3)

An alarm device that has a standby power supply and issues an alarm when it is determined that an abnormal state has occurred in a monitoring area based on a signal from a monitoring sensor,
a lightable lighting means;
a microcomputer that determines whether there is a power outage in which the supply of power from an external power supply is interrupted, and that lights the lighting means with power from the standby power supply when it is determined that the power outage has occurred;
a speaker that sounds a power restoration message when power is supplied from the external power supply after the power failure state,
The microcomputer is connected to the standby power supply via a switch that is turned on in the initial state, and is activated by power from both the external power supply and the standby power supply in the initial state. When it is determined, the switch is turned off to stop the power supply from the backup power supply, it is determined whether or not the backup power supply has started the power supply, and if it is determined that the backup power supply has started the power supply, the power failure is stopped. Prohibiting the sounding of the power restoration message even when power is supplied from the external power supply through the state
An alarm characterized by: further comprising a booster circuit for boosting the backup power supply,
2. The alarm device according to claim 1, wherein said microcomputer is activated by electric power boosted from said standby power supply by said booster circuit when it is determined that said power failure state exists. 3. The alarm device according to claim 2, wherein the microcomputer stops the power supply from the standby power supply and stops the operation of the booster circuit when it is determined that the power failure state is not detected.

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