JP4756734B2 - Alarm function notification system - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to an alarm device that detects a predetermined physical quantity and issues an alarm, and relates to an alarm device function notification system for performing notifications regarding various functions of the alarm device.
[0002]
[Prior art]
In general homes and the like, various alarm devices for detecting a fire or gas leak and issuing an alarm are widely used. Such an alarm device plays a very demanding role of monitoring the safety of ordinary houses, etc., so if an abnormality occurs in its function, this should be detected and notified to the user, etc. Is required.
For this reason, conventionally, when an abnormality is detected by electrically detecting an abnormality in each part of the alarm circuit, such as a power supply circuit of an alarm device, a fire or gas detection circuit, an alarm circuit, etc., an indication, alarm, or In addition, a function notification system has been proposed for notifying abnormality in any form, such as transfer to a control panel or monitoring center.
[0003]
[Problems to be solved by the invention]
However, in such a conventional function notification system for an alarm device, when an abnormality is detected, the notification is simply performed immediately, and the following problems have arisen.
In other words, since anomaly notification is made regardless of the user's activity time, even when the user is not in the vicinity of the alarm device, there is a possibility that the user may not notice the anomaly, or the user is asleep There is a possibility that the notification will be made even in the case of the inside and the user will be uncomfortable.
[0004]
In addition, since the notification has been made only when an abnormality is detected in the past, during the installation period of the alarm device, until the alarm device is inspected or replaced, the user must There is often no response. Therefore, the user may feel uneasy about whether or not the alarm device is functioning normally.
In addition, since the notification is made only when an abnormality is detected as described above, it is difficult to prevent the abnormality in advance.
[0005]
The present invention has been made in view of the above problems, and an object of the present invention is to provide a function notification system for an alarm device that can perform notification regarding the function of the alarm device at an optimal timing.
[0006]
In order to achieve such an object, the function notification system for an alarm device according to claim 1 notifies whether or not there is an abnormality in the function of the alarm device that detects a predetermined physical quantity or a change in physical quantity and issues an alarm. A function notification system for an alarm device for performing function detection means for determining whether or not there is an abnormality in the function of the alarm device, and determination result information indicating a determination result by the function detection means Storage means for When the predetermined physical quantity or physical quantity change detected by the alarm exceeds a predetermined threshold, Timing detection means for detecting the arrival of a notification timing for notifying whether or not there is an abnormality in the function, and when the timing detection means detects that the notification timing has arrived, the storage means And a notification means for outputting information on whether or not there is an abnormality in the function based on the stored determination result information.
[0007]
According to this system, the function state of the alarm device is detected, information on the function state is stored, and when it is detected that the notification timing has arrived, the function state is detected based on the stored information. Information is output.
Therefore, by appropriately setting the notification timing, notification can be performed when the user is in the vicinity of the alarm device, and an abnormal state or the like can be reliably notified to the user.
[0009]
According to this system, based on the physical quantity detected by the alarm device (for example, the temperature or smoke concentration detected by the fire detection means, or the hydrocarbon gas concentration or CO gas concentration detected by the gas detection means). It is detected that the notification timing has arrived.
Therefore, since the arrival of the notification timing can be determined without providing a separate detection mechanism, the alarm device can be configured simply and inexpensively.
[0010]
Also, Claim 2 The alarm function notification system described in Item 1 In the function notification system of the alarm device described above, when the determination result information stored by the storage means is information indicating that the function is normal, the notification means is information indicating that the function is normal. Is output.
[0011]
According to this system, it is detected that the function of the alarm device is in a normal state, and a message indicating that it is in a normal state is notified.
Therefore, not only when it is in an abnormal state, but also when it is in a normal state, even when a long time has passed since the installation or inspection of the alarm device, It is possible to give a sense of security to the user that the alarm device is normal.
[0012]
Also, Claim 3 The alarm function notification system according to claim 1 is provided. Or 2 In the function notification system for an alarm device described in (1), the function detection means is a state before the function of the alarm device reaches a predetermined abnormal state, and a predetermined preliminary state predicted to reach the abnormal state. When the determination result information stored in the storage means is information relating to the preliminary state, the notification means detects that the preliminary state is output.
Also, Claim 4 The alarm function notification system described in Claim 3 In the function notification system for an alarm device described in (1), the function detection means is in the preliminary state when the variation pattern of the detection output of the physical quantity or physical quantity change by the alarm device matches a predetermined abnormal variation pattern. Is detected.
[0013]
According to this system, a preliminary state that is predicted to reach an abnormal state is detected, and a message indicating the preliminary state is notified.
Therefore, not only when an abnormality occurs but also when an abnormality is likely to occur, the fact can be notified in advance, so that the prevention of the abnormality can be promoted, such as removing the cause of the abnormality at an early stage.
[0014]
Also, Claim 5 The alarm function notification system according to claim 1 is provided. To 4 In the function notification system for an alarm device described in any one of the items, the notification means outputs information on whether or not there is an abnormality in the function at intervals equal to or longer than a predetermined shortest notification interval.
[0015]
According to this system, notifications are made at intervals equal to or greater than the shortest notification interval. Therefore, by appropriately setting the shortest notification interval, notification can be performed at intervals that do not bother the user.
[0016]
DETAILED DESCRIPTION OF THE INVENTION
Embodiments of an alarm function notification system according to the present invention will be described below in detail with reference to the drawings. In this embodiment, a case will be described in which the present system is applied to a fire gas leak alarm device that detects and detects a fire and gas with a single unit. Note that the present invention is not limited to the embodiments.
[0017]
(Alarm configuration)
First, the configuration of the alarm device will be described. FIG. 1 is an overall perspective view of the alarm device, and FIG. 2 is a block diagram showing a main configuration of the alarm device.
As shown in FIG. 1, an alarm device 1 includes a substantially square housing 2, a fire detection unit 3, a gas detection unit 4, a speaker 5, a power lamp 6, a fire alarm lamp 7, a CO alarm lamp 8, and a gas. A leak alarm lamp 9 is provided.
[0018]
Of these, the fire detection unit 3 is, for example, a thermistor type or scattered light type fire detection means. Moreover, the gas detection part 4 is a gas detection means which detects hydrocarbon gas or CO gas with a gas detection element. The speaker 5 is output means for outputting a voice message or the like described later. In addition, the power lamp 6, the fire alarm lamp 7, the CO alarm lamp 8, and the gas leak alarm lamp 9 are turned on or blinked at a predetermined time to notify the user or the like of the function state or detection state of the alarm device 1. Informing means.
[0019]
As shown in FIG. 2, the alarm device 1 includes a power supply unit 10, a fire detection circuit 11, a gas detection circuit 12, a sound alarm circuit 13, an indicator lamp circuit 14, a fire transfer circuit 15, and a voltage transfer circuit 16. And a control circuit 20.
[0020]
Among these, the power supply unit 10 is connected to an AC 100 V power supply via an outlet (not shown), and supplies power to each unit of the alarm device 1.
The fire detection circuit 11 is connected to the fire detection unit 3 in FIG. 1 and outputs a voltage signal corresponding to the temperature and smoke concentration detected by the fire detection unit 3.
Further, the gas detection circuit 12 is connected to the gas detection unit 4 of FIG. 1 and outputs a voltage signal corresponding to the hydrocarbon gas or CO gas detected by the gas detection unit 4.
[0021]
The voice alarm circuit 13 is connected to the speaker 5 of FIG. 1 and outputs a voice message or the like from the speaker 5 based on the voice signal output from the control circuit 20.
The indicator lamp circuit 14 is connected to the power lamp 6, the fire alarm lamp 7, the CO alarm lamp 8, and the gas leak alarm lamp 9 shown in FIG. 1, and is based on the lighting signal or flashing signal output from the control circuit 20. Then, these lamps 6 to 9 are turned on or blinked.
[0022]
In addition, the fire transfer circuit 15 transfers information to a predetermined fire monitoring panel or the like based on the signal output from the control circuit 20. Specifically, when a fire is detected, the fire transfer circuit 15 causes a no-voltage state by short-circuiting a relay (not shown), thereby performing a transfer.
The voltage transfer circuit 16 performs transfer to a predetermined gas monitoring panel or the like based on the signal output from the control circuit 20. Specifically, the voltage transfer circuit 16 outputs 0 V when it is detected that the alarm device 1 is in a failure state, and when it is detected that the alarm device 1 is in a normal state. 6v output is performed. When hydrocarbon gas is detected, 12v output is performed. When CO gas is detected, 18v output is performed.
[0023]
The control circuit 20 is control means for controlling each part of the alarm device 1. The control circuit 20 includes a ROM (Read Only Memory) 21, a RAM (Random Access Memory) 22, an A / D (Analog Digital) converter 23, and a CPU (Central Processing Unit) 24.
[0024]
Among these, the ROM 21 is a storage unit that stores a program and data necessary for controlling each unit of the alarm device 1 in a nonvolatile manner.
In particular, the ROM 21 includes a function notification program for notifying the function of the alarm device 1, a voltage threshold value for determining the occurrence of a fire, and a voltage threshold value for determining hydrocarbon gas leakage or CO gas generation. , Voltage threshold for determining whether or not the function of each circuit is in an abnormal state, and abnormal fluctuation in voltage for determining whether or not the function of each circuit is in a state that may become abnormal in the future A pattern is stored.
The ROM 21 stores voice data of a voice message for making a notification about the function of the alarm device 1. This audio data is stored for each abnormal item described later.
[0025]
The RAM 22 is a storage unit that volatilely stores programs and data necessary for controlling each unit of the alarm device 1. In particular, the RAM 22 is a storage unit that stores information (determination result information) on the function status of each unit of the alarm device 1 detected by the CPU 24. Further, the A / D converter 23 is an analog signal of each circuit other than the control circuit 20. No., C PU24 Deal with Digital signal Convert to .
[0026]
The CPU 24 is a control unit that loads a program stored in the ROM 21 into the RAM 22 and executes the program.
In particular, the CPU 24 cooperates with each part of the alarm device 1 to detect that the function detection means for detecting the function state of the alarm device 1 and the notification timing for notifying the function state have arrived. A timing detection means for detecting and a notification means for outputting information on the state of the function based on the determination result information stored in the RAM 22 when it is detected that the notification timing has arrived are configured.
Details of specific processing performed in each of these units will be described later.
[0027]
(Content of processing)
Next, the content of the process regarding the function notification system of the alarm device 1 configured as described above will be described. FIG. 3 is a flowchart of this process.
As shown in FIG. 3, the analog outputs of the power supply unit 10, the fire detection circuit 11, the gas detection circuit 12, the sound alarm circuit 13, and the indicator lamp circuit 14 are digitally output via the A / D converter 23. The digital output is read by the CPU 24.
Then, the CPU 24 compares the output voltages of the power supply unit 10, the fire detection circuit 11, the gas detection circuit 12, the sound alarm circuit 13, and the indicator lamp circuit 14 with voltage threshold values stored in advance in the ROM 21. Thus, it is determined whether or not each unit has an abnormality (step S-1).
[0028]
Then, the CPU 24 performs the following processing according to the determination result.
First, the CPU 24 stores determination result information indicating the determination result in the RAM 22 (step S-2). Here, the determination result information includes, for example, the presence / absence of an abnormality, an abnormality item (such as a name of a circuit in which an abnormality is detected), a voltage value, and a determination time when there is an abnormality in association with each other. The
When no abnormality is detected in any of the circuits, the CPU 24 outputs a lighting signal to the indicator lamp circuit 14 to turn on the power lamp 6 in FIG. 1 (steps S-3 and S-4). . On the other hand, if an abnormality is detected in any one or more of the circuits, the CPU 24 outputs a blinking signal to the indicator lamp circuit 14 and blinks the power lamp 6 in FIG. 1 (steps S-3 and S-5). ).
[0029]
In addition, when an abnormality is detected in any one or more of the circuits, the CPU 24 outputs an abnormality signal to the fire alarm circuit 15 so that the alarm is transferred to the fire monitoring panel, etc. By outputting an abnormal signal to the reporting circuit 16, a report is sent to the gas monitoring panel or the like with 0v output (step S-6).
[0030]
However, when the occurrence of a fire or a gas leak is detected, the CPU 24 gives priority to the transfer. That is, the CPU 24 monitors the occurrence of the fire by comparing the voltage of the signal output from the fire detection circuit 11 with the threshold value of the voltage stored in the ROM 21. Further, the CPU 24 monitors hydrocarbon gas leakage and CO gas generation by comparing the voltage of the signal output from the gas detection circuit 12 with the threshold value of the voltage stored in the ROM 21.
If it is determined that there has been a fire, hydrocarbon gas leak, or CO gas has been generated, a fire signal is output to the fire alarm circuit 15 according to the contents of the fire, so that it is transferred to a fire monitoring panel or the like. In addition to performing reporting, a CO detection signal or signal is output to the voltage-transfer circuit 16 to perform a 12v output or 18v output. As a result, a quick transfer can be performed when the most urgent fire occurs, gas leaks, or CO gas is detected.
[0031]
Thereafter, the CPU 24 monitors whether or not the notification timing for notifying the function status of the alarm device 1 has arrived (step S-7). The specific contents of the determination as to whether or not the notification timing has arrived will be described later.
And when this notification timing comes, control for notifying the state of the alarm device 1 is performed. Specifically, the judgment result information stored in the RAM 22 is called (step S-8), and the voice data of the voice message corresponding to the judgment result information is called from the ROM 21 and output to the voice alarm circuit 13. Thereby, a voice message is output from the speaker 5 (step S-9).
[0032]
The specific content of this voice message is arbitrary.
For example, if the determination result information indicates that there is no abnormality, a voice message such as “Alarm 1 is operating normally” can be output. Thus, even when the alarm device 1 is normal, it is possible to give a sense of security to the user regarding the normality of the alarm device 1 by performing the notification.
For example, if the determination result information indicates that there is an abnormality, the voice data corresponding to the abnormality item included in the determination result information is called from the ROM 21 and “Fire alarm has failed. You can output a voice message such as “Please contact the maintenance company.” In this way, by making a notification when the alarm device 1 is abnormal, it is possible to notify the user of the abnormal state of the alarm device 1.
This completes a series of processing related to the function notification system.
[0033]
(Processing related to control of voice message output interval)
Here, if the voice message is output too frequently as described above, the user may be uncomfortable.
Therefore, although omitted in the flowchart of FIG. 3, in this embodiment, the output interval of the voice message is controlled.
That is, every time the voice message is output, the CPU 24 acquires the date and time by a known method and stores it in the RAM 22.
[0034]
Then, the CPU 24 calls the date and time stored in the RAM 22 before outputting the voice message, and compares this date and time with the date and time at that time, so that the time elapsed since the last voice message was output. Calculate the interval. Then, the CPU 24 stops the voice message until the elapsed interval becomes equal to or longer than a predetermined shortest notification interval (for example, 1 day to 1 week).
Alternatively, the elapse of the shortest notification interval may be monitored using timing means such as an internal timer of the CPU, and the voice message may not be output until the shortest notification interval elapses.
[0035]
(Pre-alarm processing)
In the above description, if the output from each circuit exceeds the threshold value, it is determined that there is an abnormality in each circuit, and a voice message is output. However, even if the output does not exceed the threshold, if the output fluctuation is abnormal, there is a high possibility that an abnormality will occur in the near future. For this reason, in this embodiment, prior notification (pre-alarm) is performed before abnormality notification is performed as described above.
[0036]
That is, the CPU 24 stores the output from each circuit in the RAM 22 at predetermined intervals. Then, the fluctuation pattern of this output is compared with the abnormal fluctuation pattern stored in the ROM 21, and when both coincide, even if the output from each circuit does not exceed the threshold value, the abnormal fluctuation pattern is obtained. Judgment result information indicating a match is stored in the RAM 22.
When it is determined that the notification timing has arrived as described above, the voice data of the pre-alarm voice message is called from the ROM 21 and the voice data is output to the voice alarm circuit 13. As a result, a voice message is output from the speaker 5.
[0037]
The specific content of this voice message is arbitrary.
For example, a voice message such as “The temperature is rising. Check the fire source.” Can be output. Thus, by performing the pre-alarm, it is possible to notify the user before an abnormality occurs.
[0038]
(Processing content-processing related to judgment of arrival of notification timing)
Next, specific processing for determining whether or not notification timing has arrived will be described. In order to make this determination, several processing patterns are conceivable. Therefore, each processing pattern will be described in turn below.
[0039]
(Processing content-processing concerning determination of arrival of notification timing-processing pattern 1)
First, processing pattern 1 will be described. This processing pattern 1 is processing for determining whether or not notification timing has arrived based on temperature.
Specifically, the CPU 24 monitors the temperature around the alarm device 1 at predetermined intervals. This temperature may be acquired from a newly provided temperature sensor, but can be acquired based on the voltage of the signal from the fire detection circuit 11 when the fire detection unit 3 is a thermistor type.
Next, the CPU 24 compares the temperature increase rate with a predetermined threshold value stored in the ROM 21. And when this rate of temperature rise exceeds a threshold value, it is highly likely that the user has started heating or the user has started cooking in the kitchen, and the user may be in the vicinity of the alarm device 1. It can be determined that the notification timing has arrived.
[0040]
However, when the notification timing is determined based on the temperature in this way, it is preferable to consider the difference in temperature change pattern depending on the season and the presence or absence of air conditioning. Specifically, when heating is used in winter, the difference between the lowest temperature and the highest temperature of the day is large, so that the determination based on the rate of increase in temperature is relatively accurate as described above. It can be carried out. On the other hand, in the summer, when heating is not used, the difference between the lowest temperature and the highest temperature of the day is small. Decisive It may be difficult to carry out at a time.
[0041]
For this reason, the timing can be determined based on the temperature, and the notification timing determination method can be changed according to the timing. Specifically, if the minimum temperature of the day is low (for example, 15 ° C. or less), it is determined that it is the winter season when heating is used, and the minimum temperature of the day is high (for example, 18 to If it is 20 ° C. or higher), it is determined that it is a summer season when heating is not used.
In the summer season when heating is not used, the CPU 24 determines the lowest temperature of the day by acquiring the temperature for a long period of time. Then, when a predetermined time (for example, 4 hours) elapses from the time when the minimum temperature is acquired (for example, around 4:00), the user is likely to wake up and be in the vicinity of the alarm device 1. It may be determined that the notification timing has arrived.
[0042]
However, since there are days in which the temperature does not change significantly within one day, the above determination accuracy can be improved by acquiring the temperatures of a plurality of days and learning and calculating the minimum temperature based on these temperatures. It is preferable to improve.
In addition, it is possible to make a final determination by combining not only one determination but also a plurality of determinations. For example, it may be determined that the notification timing has arrived when the rate of temperature rise exceeds a threshold and when a predetermined time has elapsed since the time when the lowest temperature was acquired.
[0043]
(Processing content-processing related to determination of arrival of notification timing-processing pattern 2)
Next, processing pattern 2 will be described. This processing pattern 2 is processing for determining whether or not the notification timing has arrived based on the smoke density. Specifically, the CPU 24 monitors the smoke density around the alarm device 1 at predetermined intervals. this Smoke density May be acquired from a newly provided smoke sensor, but can be acquired based on the voltage of the signal from the fire detection circuit 11 when the fire detection unit 3 is a scattered light type. Next, the CPU 24 compares the increase rate of the smoke density with a predetermined threshold value stored in the ROM 21. And when the increase rate of this smoke density exceeds a threshold value, it is highly likely that the user has started cooking in the kitchen, and the user is likely to be in the vicinity of the alarm device 1, It can be determined that the notification timing has arrived.
[0044]
(Processing content-processing related to determination of arrival of notification timing-processing pattern 3)
Next, the processing pattern 3 will be described. This processing pattern 3 is processing for determining whether or not notification timing has arrived based on the gas concentration.
Specifically, the CPU 24 monitors the hydrocarbon gas concentration and the CO gas concentration around the alarm device 1 at predetermined intervals. This temperature may be acquired from a newly provided gas sensor, but can be acquired based on the voltage of the signal from the gas detection circuit 12.
[0045]
Next, the CPU 24 compares the increase rate of the hydrocarbon gas concentration or the CO gas concentration with a predetermined threshold value stored in the ROM 21. Here, when the hydrocarbon gas concentration exceeds the threshold, it is highly likely that the user is using gas in the kitchen, or when the increase rate of the CO gas concentration exceeds the threshold, the user The alcohol used in the kitchen is likely detected as CO gas. Therefore, in these cases, it is highly likely that the user has started cooking in the kitchen, and it is highly likely that the user is in the vicinity of the alarm device 1, so that the notification timing has arrived. be able to.
[0046]
(Processing content-processing related to determination of arrival of notification timing-processing pattern 4)
Next, the processing pattern 4 will be described. This processing pattern 4 is processing for determining whether or not the notification timing has arrived based on light, infrared rays, or sound.
First, the case of making a determination based on light will be described. A light receiving element or the like is provided in the alarm device 1, and the amount of light received by the light receiving device is compared with a predetermined threshold value stored in the ROM 21. It is determined whether the surrounding area is a daytime state, a lighted state at night, or a lighted state at night. And since there is a high possibility that the user is in the vicinity of the alarm device 1 in the daytime state or in the lighting state at night, it can be determined that the notification timing has arrived.
[0047]
Next, the case of making a determination based on infrared rays will be described. When an infrared sensor (human sensor) is provided in the alarm device 1 and the presence of a person or the like is detected by the infrared sensor, the notification timing has arrived. Can be judged.
[0048]
Next, a description will be given of a case where a determination is made based on sound. A sound sensor is provided in the alarm device 1, and the detected sound volume by the sound sensor is compared with a predetermined threshold value stored in the ROM 21, and the detected sound volume exceeds the threshold value. If it is, the possibility that the user is in the vicinity of the alarm device 1 is high, so it can be determined that the notification timing has arrived.
[0049]
In addition to this, when an odor of a predetermined amount or more is detected by the odor sensor, when a vibration of a predetermined amount or more is detected by the vibration sensor, or when a pressure of a predetermined amount or more is detected by the pressure sensor, etc. It can be determined that the notification timing has arrived.
[0050]
Further, the determinations based on the processing patterns 1 to 4 described so far can be combined with each other to make a final determination. For example, when it is determined that the notification timing has arrived based on the temperature as in pattern 1 and it is determined that the notification timing has arrived based on the gas concentration as in pattern 3, finally, It can be determined that the notification timing has arrived.
[0051]
Although the embodiments of the present invention have been described so far, the present invention can be applied to various different embodiments in addition to the above-described embodiments within the scope of the technical idea described in the claims. May be implemented.
For example, in the above-described embodiment, an example in which a mechanism related to function notification is provided in the alarm device has been described. However, a part or all of this function may be provided outside the alarm device. For example, it is possible to electrically connect a plurality of alarm devices to a centralized monitoring panel, output judgment result information from each alarm device to the centralized monitoring panel, and perform notification by judging the notification timing in this centralized monitoring panel. Good.
[0052]
Further, in the above embodiment, the notification when the function is in an abnormal state or a normal state is performed by a voice message, but the specific form of this notification is arbitrary, for example, a simple buzzer sound or Announcement can also be made by lamp display.
Such a notification function may be switched on / off by a switching means such as a dip switch provided in the alarm device.
[0053]
【The invention's effect】
As described above, according to the present invention, the function state of the alarm device is detected, information about this state is stored, and when it is detected that the notification timing has arrived, information about the function state is output. Therefore, when the user is in the vicinity of the alarm device, notification can be performed, and the abnormal state or the like can be reliably notified to the user.
[0054]
Further, according to the present invention, since the arrival of the notification timing is detected based on the physical quantity detected by the alarm device, it is possible to determine the arrival of the notification timing without providing an individual detection mechanism. The alarm device can be configured simply and inexpensively.
[0055]
In addition, according to the present invention, it is detected that the function of the alarm device is in a normal state, and a message indicating that it is in a normal state is notified. Even when a long time has passed since the installation or inspection of the alarm device, it is possible to give the user a sense of security that the alarm device is normal.
[0056]
In addition, according to the present invention, a standby state that is predicted to reach an abnormal state is detected, and a message indicating that the state is in a preliminary state is notified. The prevention of the abnormality can be promoted by removing the cause of the abnormality at an early stage.
[0057]
Further, according to the present invention, since the notification is performed at an interval equal to or longer than the shortest notification interval, the notification can be performed at an interval that does not bother the user by appropriately setting the shortest notification interval.
[Brief description of the drawings]
FIG. 1 is an overall perspective view of an alarm device according to an embodiment of the present invention.
FIG. 2 is a block diagram showing a main configuration of an alarm device.
FIG. 3 is a flowchart of processing related to a function notification system.
[Explanation of symbols]
1 Alarm
2 Case
3 Fire detection section
4 Gas detector
5 Speaker
6 Power lamp
7 Fire alarm lamp
8 CO alarm lamp
9 Gas leak warning lamp
10 Power supply
11 Fire detection circuit
12 Gas detection circuit
13 Voice alarm circuit
14 Indicator circuit
15 Fire transfer circuit
16 Voltage transfer circuit
20 Control circuit
21 ROM
22 RAM
23 A / D converter
24 CPU

Claims (5)

A function notification system for an alarm device for notifying whether there is an abnormality in the function of an alarm device for detecting a predetermined physical quantity or a change in physical quantity and issuing an alarm,
A function detecting means for determining whether or not there is an abnormality in the function of the alarm device;
Storage means for storing determination result information indicating a determination result by the function detection means;
Timing detection that detects that the notification timing for notifying whether or not there is an abnormality in the function when the predetermined physical quantity or physical quantity change detected by the alarm exceeds a predetermined threshold Means,
When the timing detection means detects that the notification timing has arrived, based on the determination result information stored by the storage means, notification means for outputting information regarding whether or not the function is abnormal;
A function notification system for an alarm device, comprising: The notification means, when the judgment result information stored by the storage means is information indicating that the function is normal, outputs information indicating that the function is normal;
The function notification system for an alarm device according to claim 1. The function detecting means detects a predetermined preliminary state that is a state before the function of the alarm device reaches a predetermined abnormal state and is predicted to reach the abnormal state,
The notification means, when the judgment result information stored by the storage means is information relating to the preliminary state, outputs information indicating that the preliminary state;
The function notification system for an alarm device according to claim 1 or 2. The function detecting means detects the preliminary state when the fluctuation pattern of the detection output of the physical quantity or physical quantity change by the alarm device matches a predetermined abnormal fluctuation pattern.
The function notification system for an alarm device according to claim 3 . The notification means outputs information on whether or not there is an abnormality in the function at an interval equal to or longer than a predetermined shortest notification interval;
The function notification system for an alarm device according to any one of claims 1 to 4.

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