JP2021166101A - Alarm and alarm apparatus - Google Patents

Abstract

To suppress an unnecessary abnormal warning while having a function of determining whether or not communication is possible.SOLUTION: An alarm of an embodiment comprises: a communication unit that has a communication function with a predetermined external device; a notification unit that performs notification based on the state of the alarm; and a control unit that determines whether or not communication is possible between the external device and the communication unit, and controls an operation of the notification unit. When a signal from the external device is not received, the control unit determines whether or not to communicate with the external device based on a continuous or intermittent power feeding state to the alarm or the power feeding stop state. While the alarm of the embodiment comprises: a first detection unit that is constructed by the alarm of the embodiment; and a second detection unit that is constructed by a detector that communicates with the alarm of the embodiment, the alarm is powered by a commercial power source, and the detector is configured to transmit a signal to the alarm when power feeding is started from a battery.SELECTED DRAWING: Figure 4

Description

The present invention relates to an alarm device and an alarm device, and more particularly to an alarm device and an alarm device having a communication function.

In recent years, as a device for monitoring the surrounding environment and reporting an abnormality, an alarm system composed of an alarm device that operates in conjunction with a specific external device, for example, another alarm device, or a plurality of alarm devices that are linked with each other. However, it is used in factories, offices, general houses, etc. In such an alarm device and an alarm device, for example, a measurement result or an abnormality detection result of a toxic gas in one alarm device is transmitted to the other, and an alarm is issued by the other alarm device that receives the signal. For example, Patent Document 1 discloses a wirelessly interlocking type fire alarm that includes a wireless communication unit and issues a fire alarm in conjunction with another alarm.

Japanese Unexamined Patent Publication No. 2011-215903

An alarm device that communicates with a specific external device regarding the detection result, etc., communicates with the other party's device in normal times to ensure that it can communicate with the other party's device in the event of an abnormality such as a gas leak. This confirms whether or not it is possible. The alarm device disclosed in Patent Document 1 is determined to have a normal communication function by receiving a response signal to an inspection signal transmitted to another alarm device. Then, when the response signal is not received, an abnormality alarm is issued. However, in an alarm device such as Patent Document 1, an abnormality alarm is immediately issued even if a response signal is not received due to an event that may occur even in a normal state due to the configuration of the alarm device or the device of the other party. In such a case, not only is the user forced to perform an alarm stop operation that is originally unnecessary, but there is also a risk of unnecessarily arousing anxiety and reducing the trust in the alarm device.

The present invention has been made in view of such a problem, and an object of the present invention is to provide an alarm device and an alarm device capable of suppressing an unnecessary abnormal alarm while having a function of determining whether or not communication is possible.

The alarm device according to the embodiment of the present invention is an alarm device that receives power to notify an abnormality in the surrounding environment, and the alarm device includes a communication unit having a communication function with a predetermined external device and the alarm device. The control unit includes a notification unit that performs notification based on the state of the above, a control unit that determines whether or not communication is possible between the external device and the communication unit, and controls the operation of the notification unit. When the signal from the external device is not received, the determination is made based on the continuous or intermittent power supply state to the alarm device or the power supply stop state.

The control unit receives the signal from the external device in the third situation in which the alarm device is continuously supplied with power for a predetermined period in the second situation in which the signal from the external device is not received. It may be configured to control the notification unit in a second aspect that does not notify that the notification is impossible.

The control unit is different from the second aspect in that it can receive a signal from the external device in the first situation in which the communication unit is communicating with the external device. It may be configured to control the notification unit in one embodiment.

The control unit further inspects the alarm function of the alarm device, and in the first situation where the communication unit communicates with the external device, it is possible to receive a signal from the external device. At the same time, the notification unit is notified of the result of the inspection, and in the third situation, the notification unit is notified of the result of the inspection without notifying the determination result of whether or not communication with the external device is possible. It may be configured in.

The second aspect of the second aspect is that the control unit cannot receive a signal from the external device in the situation where the alarm device is not continuously supplied with power for the predetermined period in the second situation. It may be configured to notify the notification unit in a third aspect different from the above.

The alarm device further includes a storage unit in which information regarding power supply to the alarm device during the predetermined period is written, and an operated unit provided so as to be able to be operated from the outside. The information written in the storage unit is erased in response to a predetermined operation on the operated unit performed at the start of power supply to the alarm device, and the control unit is configured to erase the information written in the storage unit in the second situation. It may be configured to determine whether or not the alarm device has been continuously supplied with power for the predetermined period based on the stored contents of the storage unit.

The alarm device of another embodiment of the present invention is composed of any one of the alarm devices, and includes a first detection unit that detects a specific detection target and issues an alarm, and the external device that detects the specific detection target. As a device, it is provided with a second detection unit composed of a detector that communicates with the alarm device.

In the alarm device of another embodiment of the present invention, the alarm device is configured to be powered from a commercial power source, the detector is configured to be powered from a battery, and the power supply is started when the power supply is started. It is configured to send a signal to the alarm.

According to the present invention, it is possible to suppress an unnecessary abnormality alarm while having a function of determining whether or not communication is possible.

It is a block diagram which shows an example of the structure of the alarm device of one Embodiment of this invention. It is a front view which shows an example of the appearance of the alarm device of one Embodiment of this invention. It is a figure which shows the example of the reception state and the power supply state in the alarm device of one Embodiment. It is a flowchart which shows the confirmation process of the communication possibility in the alarm device of one Embodiment. It is a flowchart which shows the storage process of the information about the power supply during the 2nd period in the alarm device of 1 Embodiment. It is a flowchart which shows the judgment process of whether or not the communication is possible by the periodic communication in the alarm device of one Embodiment. It is a block diagram which shows an example of the structure of the alarm device of another embodiment of this invention. It is a figure which shows an example of the appearance of the alarm device of another embodiment of this invention.

Hereinafter, the alarm device according to the embodiment of the present invention will be described in detail with reference to the drawings. FIG. 1 shows an example of the configuration of the alarm device 1 of one embodiment in a block diagram.

As shown in FIG. 1, the alarm device 1 notifies based on the state of the detection unit 5 that detects a change in the surrounding environment, the communication unit 2 that has a communication function with a predetermined external device 200, and the alarm device 1. A control unit 3 that determines whether or not communication between the external device 200 and the communication unit 2 is possible, and controls the operation of the alarm device 1 as a whole, including the operation of the notification unit 6. It has. The alarm device 1 receives power from a commercial power source or a battery, and uses the detection unit 5 to monitor changes in the surrounding environment, and uses the notification unit 6 to notify the user of the alarm device 1 or the like that there is an abnormality in the surrounding environment. I will inform you. In the example of FIG. 1, the alarm device 1 further includes an operated portion 4 provided so as to be operated from the outside. Further, the alarm device 1 includes a storage unit 7 in which information regarding power supply to the alarm device 1 is written. The "predetermined external device" is subjected to preparatory processing for communication such as pairing during communication by Bluetooth (registered trademark) so that the other party can be identified and communicated with the alarm device 1. It is a device that is used.

The control unit 3 receives a signal reception state from the external device 200 by the communication unit 2 in the predetermined first period P1 (see FIG. 3), and a predetermined second period P2 (FIG. 3) prior to the first period P1. Based on the power supply state to the alarm device 1 in (see), it is configured to determine whether or not communication between the external device 200 and the communication unit 2 is possible. Therefore, according to the alarm device 1 of the present embodiment, it is possible to suppress an unnecessary abnormality alarm while having a function of determining whether or not communication is possible.

As described above, in the alarm device that communicates with a specific external device, communication for confirming whether or not communication is possible may be performed with the external device. For example, such communication is performed when the power of the alarm device and the external device is turned on, or when the user performs a predetermined operation. In the confirmation of communication availability, the alarm device waits for a signal transmitted by an external device, for example, and determines that communication is possible if the signal is received within a certain period of time. In that case, it is necessary for the external device side to send a predetermined signal during the reception waiting period in the alarm device. For example, when the user causes the alarm device to confirm whether or not communication is possible, the user performs a predetermined operation for the alarm device and also performs a predetermined operation on the external device. If the alarm and external devices are configured to perform a communicable check when the power is turned on, the user can turn on the alarm at the same time or within a short period of time by turning on both devices. Confirm whether communication is possible or not.

However, contrary to the user's intention, the alarm may be in a state of waiting for reception of a signal from an external device. For example, it is assumed that an operation for confirming whether or not communication is possible is mistakenly performed only on the alarm device. In addition, if the alarm device and the external device are configured to check whether communication is possible when the power is turned on, and if only the alarm device uses commercial power (for example, the external device uses a battery), the power failure occurs. At the time of recovery, only the alarm will be in the confirmation state of communication availability. Since the power supply to the external device continues regardless of the power failure, the external device does not transmit any signal. In such cases, even if communication with an external device is actually possible, the alarm cannot receive the signal while waiting for reception in the confirmation of communication availability, so the alarm determines that communication is not possible. It issues an abnormal alarm. It is possible to avoid such anomalous alarms if the external device constantly or frequently sends out some signal, but if the external device is a battery-powered device or the like, such multiple transmissions will generate a lot of power. It is consumed and therefore not preferable for prolonging the service life of the battery.

Therefore, in the present embodiment, the control unit 3 that determines whether or not communication is possible is not limited to the reception state of the signal SG in the predetermined first period P1 (see FIG. 3), but also the predetermined second period P2 (FIG. 3). It is configured to determine whether or not communication is possible based on the power supply state to the alarm device 1 in (see). That is, when the control unit 3 cannot receive the signal SG from the external device 200 during the predetermined first period P1, it does not immediately determine that "communication is not possible", but rather to the alarm device 1 during the second period P2. Based on the power supply status of, for example, it is possible to suspend the judgment of "communication impossible" or make a judgment different from "communication impossible". Therefore, although it is actually possible to communicate, it is possible to reduce the number of cases where it is quickly determined that "communication is not possible" and an abnormal alarm is issued based on the determination. Further, the control unit 3 determines that "communication is not possible" based on the fact that the signal SG could not be received during the first period P1 depending on the power supply state to the alarm device 1 during the second period P2. You can also. That is, according to the present embodiment, it is possible to suppress the issuance of an unnecessary abnormality alarm while having a function of determining whether or not communication is possible.

The control unit 3 includes, for example, a commercially available semiconductor device such as a microcomputer or an ASIC, and preferably has a calculation function, a comparison function, a timekeeping function, a storage function, and the like. The control unit 3 executes the timekeeping for the first period P1 and the second period P2 by, for example, its own timekeeping function. The control unit 3 can operate according to a program built in a microcomputer or the like. The built-in program describes a procedure for determining whether or not communication is possible between the external device 200 and the communication unit 2 and controlling the operation of the alarm device 1 as a whole, including the operation of the notification unit 6. .. For example, the control unit 3 is configured to operate according to a program built in a microcomputer or the like included in the control unit 3 in this way, and by operating according to the program, various controls for the communication unit 2 and the notification unit 6 and the like can be performed. Can be done.

The "power supply state" to the alarm device 1 in the second period P2, which can be the basis for determining whether or not communication is possible, includes, for example, the continuity of power supply and the number of times the start and stop of power supply are repeated during the second period P2. , The length of the power supply stop period, etc. are exemplified. For example, when the alarm device 1 is continuously supplied with power during the second period P2, the control unit 3 immediately "cannot communicate" even if the signal SG is not received during the first period P1. It is not necessary to judge. If the alarm device 1 is continuously supplied with power for a longer period than a predetermined length period (second period P2), that is, if it is operating normally, even during a limited period (first period P1). This is because even if the signal SG is not received, it can be estimated that the external device 200 is not in the state of transmitting the signal SG.

Further, when the control unit 1 repeatedly starts and stops supplying power to the alarm device 1 more than a predetermined number of times during the second period P2, or during the second period P2, the control unit 1 has a predetermined length. If the power supply is stopped within the range, it may be configured so that it is not immediately determined that "communication is not possible" even if the signal SG is not received during the first period P1. For example, after installing the alarm device 1, when it is sufficiently confirmed that communication with the external device 200 is possible, the installation procedure of intermittently supplying power a predetermined number of times or stopping the power supply for a predetermined period is known to the contractor and the like. If such an operation is actually performed, it can be presumed that the inability to receive during the first period P1 is simply due to the external device 200 not transmitting the signal SG. ..

According to the control of the control unit 3, the communication unit 2 performs mutual conversion between the signal in the alarm device 1 and the signal used for communication, and transmits / receives the signal to / from the specific external device 200. In particular, in the present embodiment, as described above, the communication unit 2 receives the signal SG for confirming whether or not communication with the external device 200 is possible. The communication unit 2 may be composed of hardware such as an integrated circuit device or an electric circuit composed of individual electric components. The communication unit 2 may share hardware with the control unit 3 or may be incorporated in the control unit 3. Further, the communication unit 2 may include software such as a program in which a process to be executed by itself is described.

The operated unit 4 is provided so that it can be operated by a user or the like from the outside of the alarm device 1. For example, the operated portion 4 is composed of an arbitrary circuit switch (switch) such as a push button type, a toggle type, or a slide type. Further, the operated unit 4 changes the state by being operated by a user or the like, and an arbitrary input that outputs a predetermined signal (for example, a high level signal or a low level signal) according to the state to the control unit 3. It may be configured by means. For example, the operated unit 4 may be a keyboard, a touch panel, or the like, and may be composed of a microphone and a voice recognition means that outputs a signal corresponding to the voice. The operated unit 4 may also be used as an inspection switch operated by a user or the like to instruct the alarm device 1 to perform a self-inspection. That is, the control unit 3 is configured to perform an inspection of the alarm function in the alarm device 1 by executing an inspection program in which a predetermined inspection procedure is described in response to an operation on the operated unit 4. May be good.

The detection unit 5 is mainly composed of various sensors that monitor a physical phenomenon in a monitoring target area around the alarm device 1 and output the result. Various sensors include, for example, various gas sensors that detect carbon monoxide (CO) gas, methane gas (CH ₄ ), propane gas (C ₃ H ₈ ), etc., as well as temperature sensors, humidity sensors, smoke sensors, etc. Sensors, odor sensors and the like are exemplified. The detection unit 5 may include one or a plurality of sensors.

The notification unit 6 is configured by means for notifying a user or the like, such as a light emitting diode (LED), a buzzer and / or a speaker, and mainly emits an alarm by emitting light and / or sound. In addition to issuing an alarm, the notification unit 6 also changes the monitoring area that does not issue an alarm, the result of the determination by the control unit 3 regarding whether or not communication with the external device 200 is possible, and the alarm device 1. It may operate for notifying the result of the inspection of the alarm function.

The storage unit 7 is a storage area in which information regarding power supply to the alarm device 1 in the second period P2 is written, and may be provided inside the control unit 3 as shown in FIG. May be separately provided in the alarm device 1. The storage unit 7 is mainly composed of a semiconductor memory, but includes at least a non-volatile storage area such as a ROM or a flash memory. Preferably, information regarding the power supply state of the alarm device 1 in the second period P2 (see FIG. 3) is written in the non-volatile storage area of the storage unit 7. For example, the storage unit 7 may include a register for a continuous power supply flag, which is a flag indicating whether or not the alarm device 1 has been continuously supplied during the second period P2, and may include a register for the continuous power supply flag. A storage space for storing states may be included in the non-volatile storage area. The continuous power supply flag will be described in detail later. Further, the storage unit 7 is a storage space that stores the number of times that the start and stop of power supply are repeated during the second period P2, or the power supply is supplied within a predetermined range during the second period P2. The non-volatile storage area may include a storage space for a flag indicating whether or not it has been stopped.

FIG. 2 shows an example of the appearance of the alarm device 1 of the present embodiment. The alarm device 1 includes a housing 11 formed in a substantially rectangular parallelepiped shape, and the control unit 3 and the communication unit 2 shown in FIG. 1 are housed in the housing 11. The housing 11 has a display unit 61 that visually notifies that the alarm device 1 is being supplied with power and that the external environment is in an abnormal state, an alarm sound emitted inside the housing 11, and the like. A sound emitting unit 62 for emitting a sound is provided. The display unit 61 and the sound emitting unit 62 are responsible for the notification function of the notification unit 6 (see FIG. 1) described above.

The housing 11 is further provided with an operated portion 4. The operated unit 4 is provided in the housing 11 so that it can be pressed from the front F side where the display unit 61 or the like is provided in the housing 11. When the alarm device 1 of the present embodiment has the housing 11 shown in FIG. 2, a predetermined signal may be input to the control unit 3 by pressing the operated unit 4, and the control unit may input a predetermined signal based on the signal. 3 may control the operation of the communication unit 2 and the notification unit 6. If the operated unit 4 is also an inspection switch operated to instruct the alarm device 1 to perform an inspection, the user may have the alarm device 1 perform the inspection by pressing the operated unit 4. can.

In FIG. 2, the power plug 1a is connected to the power cord extending from the lower side of the housing 11. In the alarm device 1, even if the power supply and stop of the components such as the control unit 3, the communication unit 2, the notification unit 6 and the detection unit 5 are performed by inserting and removing the power plug 1a into the outlet of the commercial power supply. good. Further, a power switch or the like may be separately provided, and the supply and stop of power to each component may be switched by operating the power switch. Then, when the power supply is started by inserting the power plug 1a into the outlet or operating the power switch, the control unit 3 confirms whether or not communication with the external device 200 (see FIG. 1) is possible. You may go. Further, the control unit 3 may check the alarm function of the alarm device 1 as well as confirm whether or not communication is possible when the power supply is started.

Next, the control unit 3 determines whether or not communication with the external device 200 is possible based on the presence or absence of reception of the signal SG from the external device in the first period P1 and the presence or absence of continuous power supply during the second period P2. The operation of the alarm device 1 according to the embodiment will be described by taking as an example the case where the alarm device 1 is configured to perform the above. FIG. 3 shows first to fourth examples EX1 to EX4 regarding the reception state of the signal SG in the first period P1 and the power supply state in the second period P2. In FIG. 3, the rectangle with the symbol V and extending in the horizontal axis direction indicates that power is being supplied to the alarm device 1. Further, the arrow with the code SG indicates a signal transmitted from the external device 200 (see FIG. 1) and to be received by the communication unit 2 (see FIG. 1) of the alarm device 1. In the example of FIG. 3, the first period P1 is a period of a predetermined length starting from the first time point T1 when the power supply to the alarm device 1 is started. Further, the second period P2 is a predetermined time starting from the second time point T2 when it is determined that the communication unit 2 and the external device 200 can communicate with each other after the start of power supply to the alarm device 1 preceding the first time point T1. The period of length. The first period P1 and the second period P2 are not particularly limited, but the second period P2 is at least longer than the first period P1. For example, the first period P1 is a time of about 5 minutes or less at the longest, such as 30 seconds, 1 minute, 2 minutes, or 3 minutes. For example, the second period P2 is 12 hours, 24 hours, or 72 hours. It takes about half a day or more and five days or less.

Here, in the "second time point T2 determined to be able to communicate with the external device 200", for example, as shown in FIG. 3, the signal SG communicates during the power supply period before the first time point T1. This is exactly when it was received by Part 2. When the signal SG is received a plurality of times in the power feeding period before the first time point T1, the second time point T2 may be any reception time point. Further, the time from the reception of the signal SG to the determination by the control unit 3 based on the reception is, for example, the minimum unit of timekeeping of the second period P2 by the control unit 3 (for example, 1 second unit, 30 second unit, or 1 minute). If it is longer than the unit), the second time point T2 may be the time when the determination is made by the control unit 3. The second time point T2, which is the starting point of the second time period P2, does not necessarily have to be the time when it is determined that communication with the external device 200 is possible. For example, the power supply period before the first time point T1. It may be the start time of.

In FIG. 3, the first example EX1 is an example of the first situation in which the signal SG from the external device 200 is received by the communication unit 2 in the first period P1. In this first situation, the control unit 3 can communicate with the external device 200 based on the fact that the signal SG is received during the first period P1 regardless of the power supply state in the second period P2. You may judge that. Then, the control unit 3 may notify the notification unit 6 in a predetermined first mode that the signal SG can be received from the external device 200. For example, as the first aspect, the LED constituting the display unit 61 (see FIG. 2) may be turned on, and / or a buzzer sound or a message may be emitted from the sound emitting unit 62 (see FIG. 2). .. Further, as described above, when the control unit 3 confirms whether communication is possible and checks the alarm function of the alarm device 1, the control unit 3 receives the signal SG from the external device 200 in the first situation. The notification unit 6 may be notified of the result of the inspection of the alarm function. That is, the first aspect may include notification of the inspection result of the alarm function. For example, when the alarm function is normal, the LED of the display unit 61 lights up and the "alarm device is normal" as the first aspect. The message "Radio waves have been received" may be emitted from the sound emitting unit 62.

In FIG. 3, the second example EX2 is an example of the second situation in which the signal SG from the external device 200 is not received by the communication unit 2 in the first period P1, and further, the alarm device in the second situation. 1 is an example of a third situation in which power is continuously supplied during the second period P2. In this third situation, the signal SG was not received in the first period P1, but the alarm device 1 was continuously supplied with power during the second period P2, so that the control unit 3 has elapsed the first period P1. Immediately after that, it is not judged whether or not communication between the alarm device 1 and the external device 200 is possible. Therefore, in the third situation, the control unit 3 does not immediately notify the notification unit 6 that the signal SG cannot be received from the external device 200, and the notification unit 6 is in a second mode different from the first mode. Make a notification. For example, in the second aspect, an LED different from the LED lit in the first aspect of the display unit 61 may be lit, the LED lit in the first aspect may be blinking, and a sound may be emitted. A sound having a frequency different from that of the first aspect may be emitted from the unit 62, or a sound may be emitted intermittently at a timing different from that of the first aspect. However, in this second aspect, it is not notified that the signal SG cannot be received from the external device 200. Further, when the control unit 3 confirms whether or not communication is possible and checks the alarm function of the alarm device 1, in the third situation, the control unit 3 informs the notification unit 6 whether or not communication is possible with the external device 200. The result of the inspection of the alarm function may be notified without notifying the judgment result of. That is, the second aspect may include only notification of the inspection result of the alarm function. For example, as the second aspect, the message "alarm device is normal" may be emitted from the sound emitting unit 62.

In FIG. 3, the third example EX3 and the fourth example EX4 are both examples of the second situation in which the signal SG is not received in the first period P1 like the second example EX2, but the second situation. This is an example of a fourth situation in which the alarm device 1 is not continuously supplied with power during the second period P2. The third example EX3 is an example in which the alarm device 1 is not supplied with any power during the second period P2. Further, in the fourth example EX4, the total power supply time before the first time point T1 is longer than that of the second period P2, but the power supply is not continuously performed in the second period P2, and the power supply time in each power supply is increased. Is an example shorter than the length of the second period P2. In this fourth situation, the control unit 3 notifies the notification unit 6 that the signal SG cannot be received from the external device 200. For example, the control unit 3 causes the notification unit 6 to execute the notification in a third aspect different from both the first and second aspects.

In the third aspect, the display unit 61 may blink at an interval different from the blinking interval in both the first and second aspects, and a frequency different from any of the frequencies of the sounds emitted in the first and second aspects. The sound of may be emitted from the sound emitting unit 62. For example, as a third aspect, the sound emitting unit 62 may emit a message "No radio waves can be received" following an electronic sound or a buzzer sound. Further, when the external device 200 is a carbon monoxide detector, the message "The radio wave of the CO detection unit cannot be received" may be issued instead of "The radio wave cannot be received". When the control unit 3 confirms whether communication is possible and inspects the alarm function of the alarm device 1, the control unit 3 cannot receive the signal SG and notifies the inspection result of the alarm function to the notification unit 6. May be notified. However, in the fourth situation, only the fact that the signal SG cannot be received may be notified. It is considered that this can encourage users and the like to take measures to restore communication with the external device 200.

Next, the procedure for determining whether or not communication is possible based on the reception state of the radio wave from the external device 200 in the first period P1 and the power supply state in the second period P2 will be described with reference to FIG. 4 showing the flow in the form of a flowchart. do. First, in step S0 (first time point T1), power supply is started, or a predetermined operation by the user starts a process of confirming whether or not communication with the external device 200 is possible. Timekeeping begins. In step S1, it is determined whether or not the first period P1 has elapsed, and if the first period P1 has not yet elapsed (“N” in step S1), whether or not a signal has been received from the external device 200 is present. It is determined (step S2). If the signal from the external device 200 is not received (“N” in step S2), the control returns to step S1 until the first period P1 elapses or the signal from the external device 200 is received in step S1. And step S2 are repeated (loop R1).

When the signal from the external device 200 is received in step S2 (“Y” in step S2), the control unit 3 causes the notification unit 6 to execute the notification in the above-described first mode (step S4). That is, the alarm device 1 is in the first situation described above. At this time, the control unit 3 may store, for example, a storage unit 7 (see FIG. 1) with predetermined information indicating that the signal has been received (step S3). For example, the control unit 3 may set a specific flag (hereinafter, also referred to as a “signal reception flag”) provided in the storage area in the storage unit 7. The signal reception flag is preferably provided in a volatile storage area where the stored contents are erased when the power supply to the alarm device 1 is stopped. How to use the signal reception flag will be described later.

On the other hand, when the passage of the first period P1 is detected in step S1 (“Y” in step S1), the alarm device 1 is in the above-mentioned second situation, and in step S5, the power supply state of the second period P2 is related. Judgment is carried out. The control unit 3 determines, for example, whether or not the alarm device 1 has been continuously supplied with power during the second period P2 based on the stored contents of the storage unit 7. When the storage unit 7 stores predetermined information indicating that the alarm device 1 has been continuously supplied with power during the second period P2, the control unit 3 affirms the power supply state of the second period P2. Judgment (“Y” in step S5). For example, if the above-mentioned continuous power supply flag is set, the control unit 3 makes a positive judgment regarding the power supply state of the second period P2. In that case, the alarm device 1 is in the third situation described above, and the control unit 3 causes the notification unit 6 to execute the notification in the second mode described above without immediately determining whether or not communication with the external device 200 is possible (the second mode described above). Step S6).

The determination regarding the power supply state of the second period P2 in step S5 may be made on the basis of other than the continuity of power supply during the second period P2. As described above, the basis for the determination may be the number of repetitions of the start and stop of power supply during the second period P2, the length of the power supply stop period, and the like. The storage unit 7 indicates the number of times that the start and stop of power supply are repeated during the second period P2, or whether or not the power supply is stopped within a predetermined range during the second period P2. The information is stored, and the control unit 3 may make a determination in step S5 by referring to the information.

If a negative determination is made regarding the power supply state of the second period P2 in step S5 (“N” in step S5), the alarm device 1 is in the above-mentioned fourth situation, and the control unit 3 is in the above-mentioned third situation. The notification unit 6 is made to execute the notification in the embodiment (step S7).

FIG. 5 shows a processing routine that determines whether or not the alarm device 1 is continuously supplied with power during the second period P2, and stores predetermined information in the storage unit 7 or the like when the alarm device 1 is continuously supplied with power. The flowchart of is shown. FIG. 5 shows an example in which the above-mentioned continuous power supply flag is set as storage of predetermined information performed when the alarm device 1 is continuously supplied with power during the second period P2. The storage of information performed when the alarm device 1 is continuously supplied with power is not limited to a set of some flags. The storage of such information may be a predetermined storage of specific information having an arbitrary bit length in an arbitrary storage area inside or outside the storage unit 7.

The series of processes shown in FIG. 5 is performed every predetermined time, for example, every second, 30 after, for example, after the start of power supply to the alarm device 1 and preferably after the execution of the confirmation of communication availability shown in FIG. It is repeatedly executed every second, every minute, and so on. Further, when the process shown in FIG. 5 is executed, for example, the control unit 3 has a counter (not shown) whose count value is reset when the power supply is started or stopped, and this counter is used for the second period P2. It is used for timing.

As shown in FIG. 5, when the processing routine is started in step SA0, it is determined whether the continuous power supply flag has already been set (step SA1), and when the continuous power supply flag is set (in step SA1, " Y ”) terminates the processing routine shown in FIG. Even if the processes after step SA2 are executed when the continuous power supply flag is already set, the continuous power supply flag that has already been set is not reset, so that no particular problem occurs. Therefore, step SA1 may be omitted.

When the determination in step SA1 is "N", it is determined in step SA2 whether or not the power supply is continued. In the example of FIG. 5, it is determined whether or not the power supply is continued depending on whether or not the above-mentioned signal reception flag is set. The signal reception flag is set when a signal from the external device 200 is received in the process shown in FIG. 4 as described above or in the periodic communication described later. Further, as described above, the signal reception flag is preferably provided in the volatile storage area of the storage unit 7 or the like, and is reset when the power supply to the alarm device 1 is stopped. In that case, by referring to the signal reception flag, was the alarm device 1 continuously supplied with power in the second period P2 after receiving the signal from the external device 200 (after the second time point T2 (see FIG. 3))? It can be determined whether or not.

When the alarm device 1 is continuously supplied with power from the second time point T2 (“Y” in step SA2), a counter (not shown) is counted up (step SA3), and in step SA4, has the second period P2 passed? Whether or not it is judged. For example, the elapsed time obtained by the product of the count value of the counter and the time interval (such as 1 second, 30 seconds, or 1 minute described above) in which the series of processes shown in FIG. 5 is executed is the second period P2 (second period). The length of period P2) is compared. If the elapsed time is less than the second period P2, it is determined that the second period P2 has not elapsed (“N” in step SA4), and the process shown in FIG. 5 ends.

On the other hand, when the product of the count value of the counter and the execution interval of the process of FIG. 5 is equal to or greater than the second period P2, it is determined that the second period P2 has elapsed (“Y” in step SA4), and the continuous power supply flag. Is set (step SA5). The continuous power feeding flag is preferably provided in a volatile storage area such as a register in the storage unit 7 so that the control unit 3 can quickly refer to the state. Therefore, for example, the state of the continuous power supply flag is stored in the non-volatile storage area in the storage unit 7 so that the information about the power supply state in the second period P2 can be retained until the time when the power supply is restarted when the power supply is stopped. (Step SA6). When the power supply to the alarm device 1 is temporarily stopped and then the power supply is restarted (first time point T1), the information stored in this non-volatile storage area is read out, and the continuous power supply flag is set based on the information. Can be set. As a result, it becomes possible to determine the continuity of power supply during the second period P2 in step S5 of FIG.

If the alarm device 1 is not continuously supplied with power from the second time point T2 (“N” in step SA2), the count value of a counter (not shown) is reset (step SA7), and the process shown in FIG. 5 ends. .. Since the count value is reset in this way, the control unit 3 performs the second in the case of the fourth example EX4 in FIG. 3 referred to earlier, even if the total power supply time is longer than the second period P2. It can be determined that the alarm device 1 is not continuously supplied with power during the period P2.

In step SA2, whether or not the power supply is continued may be determined by monitoring the voltage to be supplied without using the signal reception flag. In that case, step S3 in FIG. 4 may be performed. It may be omitted. Further, in that case, instead of the counter (not shown), the target time is set to the length (time) of the second period P2, and the timer circuit starts when the signal from the external device 200 is received and is reset when the power supply is stopped. May be provided in the alarm device 1 and used for timing the second period P2. However, judging only by the monitor of the feeding voltage, the continuous feeding flag may be set even if the signal from the external device 200 is not received during the second period P2. That is, it is determined in step S5 that the alarm device 1 is in the third situation even though the power is continuously supplied during the second period P2, but communication with the external device 200 is not possible. Is also possible. Therefore, it is preferable to use the signal reception flag to determine the continuity of power supply during the second period P2.

Further, as described above, the determination regarding the power supply state of the second period P2 in step S5 of FIG. 4 is performed based on the number of repetitions of the start and stop of power supply during the second period P2, the length of the power supply stop period, and the like. In this case, the non-volatile storage area of the storage unit 7 can be used. For example, the numerical value stored in the non-volatile storage area may be increased by 1 each time the power supply is started during the second period P2. Further, when the power supply is stopped for a period within a predetermined range during the second period P2, the predetermined information may be stored in the non-volatile storage area of the storage unit 7. When the power supply is stopped in the second period P2 in this way, the timekeeping for determining the passage of the second period P2 may be performed by receiving information on the elapsed time from the external device 200. This may be done by receiving standard radio waves.

In the example of FIG. 5, the information regarding the power supply state to the alarm device 1 in the second period P2 (hereinafter, this information is also simply referred to as “power supply state information”) is continuous in the non-volatile storage area of the storage unit 7. The state of the power supply flag is stored. Therefore, even if the power supply is stopped, the information indicating that the alarm device 1 has been continuously supplied with power during the second period P2, for example, is not erased. However, the alarm device 1 may be configured so that the power supply state information once stored in the storage unit 7 can be erased. For example, when information on continuous power supply is stored in the non-volatile storage area due to continuous power supply during aging during the manufacturing process of the alarm device 1, it is preferable to erase this information in preparation for installation after shipment. .. Therefore, for example, the storage unit 7 may erase the power supply state information in response to a predetermined operation on the operated unit 4 (see FIGS. 1 and 2).

Here, as described above, the operated unit 4 can be used not only for instructing the alarm device 1 to inspect, but also for stopping the alarm when the alarm is issued. Therefore, from the viewpoint of preventing erroneous operation, it is preferable that the operation on the operated unit 4 for erasing the power supply state information is an operation that is not easily confused with an operation for another purpose by a user or the like. Therefore, such an operation may be a complex operation combined with an operation other than the operation for the operated portion 4, for example, the alarm device 1 by inserting the power plug 1a (see FIG. 2) into the outlet. It may be an operation performed on the operated unit 4 at the start of power supply to. When the operated unit 4 has a structure to be pressed as shown in FIG. 2, the power supply state information may be erased by inserting the power plug 1a into the outlet while pressing the operated unit 4. Further, not only the power supply is started while pushing the operated portion 4 but also the pushing to the operated portion 4 is continued for a predetermined time such as 3 seconds, 5 seconds, or 10 seconds after the power feeding is started. The power supply status information may be deleted by.

As described above, in the third situation (see FIGS. 3 and 4), the control unit 3 does not immediately determine whether or not communication with the external device 200 is possible, and notifies the notification unit 6 in the second aspect. Let it run. However, even if the control unit 3 suspends the determination of whether or not communication is possible in this way, it is preferable that the control unit 3 is based on the presence or absence of reception of a signal from the external device 200, apart from the determination of whether or not communication is possible after the first period P1. It is periodically determined whether or not communication with the external device 200 is possible. Then, the notification unit 6 is made to execute the notification in an appropriate manner based on the determination result. An example of the process of determining whether or not communication is possible by periodic communication with the external device 200 in the alarm device 1 will be described with reference to FIG. 6 showing the flow of the process. In FIG. 6, the flow shown on the left side shows the flow of processing in the alarm device 1, and the flow shown on the right side shows the flow of processing executed by the external device 200.

The series of processes shown in FIG. 6 are repeatedly executed after being started (steps SB0 and SC0) by, for example, starting power supply to the alarm device 1 and the external device 200. Further, in the example of FIG. 6, when the signal SG from the external device 200 is not received during the third period P3, it is determined that the communication with the external device 200 is impossible. The external device 200 periodically transmits a signal SG to the alarm device 1 in a cycle P4 shorter than that of the third period P3. The alarm device 1 is provided with a third period timekeeping timer (not shown) for monitoring the progress of the third period P3, and after the start in step SB0, the third period timekeeping timer starts operation. After that, the timekeeping operation is continued. The third period P3 is shorter than the above-mentioned second period P2 and longer than the cycle P4 in which the external device 200 transmits the signal SG. The external device 200 is provided with a periodic timekeeping timer (not shown) for monitoring the progress of the period P4, and after the start in step SC0, the periodic timekeeping timer starts the operation and then continues the timekeeping operation. do.

In the external device 200, in step SC1, it is determined whether or not the cycle P4 has elapsed by referring to the cycle timing timer. If cycle P4 has not elapsed (“N” in step SC1), step SC1 is repeated in loop R3. Then, when the period P4 elapses (“Y” in step SC1), the signal SG is transmitted to the alarm device 1 (step SC2). Then, the periodic timekeeping timer is reset (step SC3), and control is returned to step SC1 in loop R3. In this way, the signal SG is transmitted from the external device 200 in the cycle P4.

In the alarm device 1, when the signal SG from the external device 200 is received in step SB1 (“Y” in step SB1), the signal reception flag described above is preferably set (step SB2). Then, the third period timekeeping timer is reset (step SB6), and control is returned to step SB1 in loop R2. If the signal SG is not received in step SB1 (“N” in step SB1), it is determined whether or not the third period P3 has elapsed by referring to the third period timekeeping timer (step SB3). If the third period P3 has not elapsed (“N” in step SB3), control is returned to step SB1 in loop R2.

If it is determined that the third period P3 has elapsed (“Y” in step SB3), the control unit 3 determines that communication with the external device 200 is impossible, and the notification unit 6 (see FIG. 1). ), For example, in the third aspect described above (step SB4). That is, it is notified that the signal SG cannot be received from the external device 200. Further, the control unit 3 preferably resets the signal reception flag (step SB5). Then, the third period timekeeping timer is reset (step SB6), and the control is returned to step SB1. Even if the judgment as to whether or not communication with the external device 200 is possible is suspended after the lapse of the first period P1, preferably, the judgment as to whether or not communication with the external device 200 is possible is made through periodic communication in this way, and the judgment is made. Based on the result, it is notified that communication with the external device 200 is not possible.

Next, the alarm device of another embodiment of the present invention will be described. FIG. 7 shows an example of the configuration of the alarm device 100 of another embodiment in a block diagram, and FIG. 8 shows an example of the appearance of the alarm device 100 of another embodiment. As shown in FIG. 7, the alarm device 100 includes a first detection unit 110 that detects a specific detection target and issues an alarm, and a second detection unit 120 that includes a detector 10 that detects the specific detection target. And have. The first detection unit 110 is composed of the alarm device 1 of the above-described embodiment. The detector 10 communicates with the alarm device 1 (first detection unit 110) as the external device 200 described above.

The second detection unit 120 preferably detects a detection target different from the detection target of the first detection unit 110. For example, when the detection target of the first detection unit 110 is propane gas, the second detection unit 120 may detect carbon monoxide gas, methane gas, or the like. When the second detection unit 120 detects the detection target gas at a concentration equal to or higher than a predetermined threshold value, the second detection unit 120 itself may issue an alarm, and the detection information is transmitted to the first detection unit 110 to perform the second detection. An alarm regarding the gas to be detected by the unit 120 may be further issued by the first detection unit 110.

In the example of FIG. 7, the detector 10 constituting the second detection unit 120 includes a communication unit 122, a control unit 123, an operated unit 124, a detection unit 125, and a notification unit 126, similarly to the alarm device 1. .. Communication is exchanged between the communication unit 122 and the communication unit 2 of the alarm device 1. The detector 10 does not necessarily have all the components shown in FIG. 7, and may be configured so as to be able to detect at least one detection target and communicate with the alarm device 1. When the detector 10 includes each component shown in FIG. 7, the component may have the same configuration as each component constituting the alarm device 1 described above. Therefore, in the description of the alarm device 100, the description of each component constituting the detection unit 10 (second detection unit 120) is omitted.

As shown in FIG. 8, the detector 10 includes a display unit 1261 that visually notifies that the detector 10 is being supplied with power and that the external environment is in an abnormal state. Further, the operated portion 124 used as an alarm stop switch or the like is provided on the front surface of the housing 121 so that it can be operated from the outside. Further, the detector 10 is provided with a second operated portion 128 provided on the side surface so as to be pushed toward the inside of the housing 121.

In the alarm device 100, the alarm device 1 constituting the first detection unit 110 is configured to be supplied with power from a commercial power source. On the other hand, the detector 10 constituting the second detection unit 120 is configured to be supplied with power from the battery. Then, the detector 10 is configured to transmit a signal SG to the alarm device 1 when the power supply is started. Therefore, as described above, when the power supply to the alarm device 1 and the detector 10 is started substantially simultaneously, or at worst, without a gap of P1 or more in the first period, the communication unit of the alarm device 1 is started. The signal SG from the detector 10 is received by 2. Thereby, it can be confirmed that the alarm device 1 can communicate with the detector 10. On the other hand, at the time of recovery from a power failure, the signal SG is not always transmitted from the detector 10 at the timing corresponding to the recovery from the power failure, and the alarm device 1 is detected during the first period P1 (see FIG. 3). The signal SG from 10 may not be received. However, in the alarm device 100, as described above, the control unit 3 of the alarm device 1 constituting the first detection unit 110 is based on the power supply state to the alarm device 1 in the second period P2 (see FIG. 3). Since it is determined whether or not communication with the detector 10 is possible, unnecessary abnormality alarms can be suppressed.

The electric power supplied from the battery in the detector 10 may be directly supplied to each element constituting the detector 10, but it is detected by pushing the second operated portion 128 into the housing 121. Power supply to each element constituting the vessel 10 may be started. That is, the detector 10 may transmit a signal SG to the alarm device 1 when the second operated portion 128 is pushed into the housing 121.

The first detection unit 110 and the second detection unit 120 may perform the periodic communication described with reference to FIG. 6 as the communication between the alarm device 1 and the external device 200. In that case, the detector 10 periodically transmits the signal SG to the alarm device 1 constituting the first detection unit 110 as the external device 200. That is, the detector 10 transmits the signal SG to the alarm device 1 in a predetermined period P4 which is longer than the first period P1 and shorter than the second period P2. The cycle P4 is not particularly limited, but since power is consumed for each transmission, for example, the cycle is as short as possible within the range in which the battery life of the detector 10 is not shorter than the useful life of the gas sensor provided in the detector 10. P4 is preferable. For example, as the cycle P4, 4 hours, 8 hours, 12 hours, and the like are exemplified.

On the other hand, the control unit 3 of the alarm device 1 cannot receive the signal from the detector 10 when the signal from the detector 10 is not received by the communication unit 2 during the predetermined third period P3. The notification unit 6 is notified. In this case, the notification unit 6 executes notification in, for example, the third aspect described above. The third period P3 is longer than the predetermined period P4 in which the signal SG is transmitted and shorter than the second period P2. As the third period P3, a period of about 0.5 hours, 1 hour, or 2 hours longer than that of the second period P2 communicates promptly while allowing a timing error between the alarm 1 and the detector 10. It is preferable in that it can notify the inability. By performing such regular communication, even if the judgment as to whether or not the alarm device 1 and the detector 10 can be communicated is suspended after the lapse of the first period P1, the feasibility of the communication is subsequently determined. Can be judged appropriately. That is, when communication is actually impossible, it is possible to notify the user or the like that communication is impossible.

It should be noted that the embodiments disclosed this time are exemplary in all respects and are not considered to be restrictive. The scope of the present invention is shown by the scope of claims rather than the description of the above-described embodiment, and further includes all modifications (modifications) within the meaning and scope equivalent to the scope of claims.

Further, in the above embodiment, for convenience of explanation, the processing operation of the alarm device of the embodiment has been described using a flow-driven flowchart in which processing is performed in order along the processing flow, but the present invention is not limited to this. .. In the present invention, the processing operation of the alarm device may be performed by event-driven (event-driven) processing that executes processing on an event-by-event basis. In this case, it may be completely event-driven, or it may be a combination of event-driven and flow-driven.

1 Alarm 2 Communication unit 3 Control unit 4 Operated unit 6 Notification unit 7 Storage unit 10 Detector 100 Alarm device 110 1st detection unit 120 2nd detection unit 128 2nd operated unit 200 External device P1 1st period P2 1st 2 period P3 3rd period P4 Predetermined cycle T1 1st time point T2 2nd time point

Claims (7)

An alarm device that receives power to notify an abnormality in the surrounding environment, and the alarm device is
A communication unit that has a communication function with a predetermined external device,
A notification unit that performs notification based on the state of the alarm, and
It is provided with a control unit that determines whether or not communication is possible between the external device and the communication unit and controls the operation of the notification unit.
When the signal from the external device is not received, the control unit is configured to make the determination based on the continuous or intermittent power supply state to the alarm device or the power supply stop state. .. The control unit receives the signal from the external device in the third situation in which the alarm device is continuously supplied with power for a predetermined period in the second situation in which the signal from the external device is not received. The alarm device according to claim 1, wherein the alarm device is configured to control the notification unit in a second aspect that does not notify that the notification is impossible. The control unit is different from the second aspect in that it can receive a signal from the external device in the first situation in which the communication unit is communicating with the external device. The alarm device according to claim 2, which is configured to control the notification unit in one embodiment. The control unit further
Check the alarm function of the alarm device and check it.
In the first situation in which the communication unit communicates with the external device, the notification unit is notified of the result of the inspection while being able to receive the signal from the external device.
The alarm device according to claim 2 or 3, wherein in the third situation, the notification unit is configured to notify the result of the inspection without notifying the result of determining whether or not communication with the external device is possible. .. The second aspect of the second aspect is that the control unit cannot receive a signal from the external device in the second situation in which the alarm device is not continuously supplied with power for the predetermined period. The alarm device according to any one of claims 2 to 4, which is configured to notify the notification unit in a third aspect different from the above. The alarm device further includes a storage unit in which information regarding power supply to the alarm device during the predetermined period is written, and an operated unit provided so as to be able to be operated from the outside.
The storage unit is configured to erase the information written in the storage unit in response to a predetermined operation on the operated unit performed at the start of power supply to the alarm device.
The control unit is configured to determine in the second situation whether or not the alarm device has been continuously supplied with power for the predetermined period based on the stored contents of the storage unit. The alarm according to any one of 2 to 5. A first detection unit, which is composed of the alarm device according to any one of claims 1 to 6 and detects a specific detection target and issues an alarm.
An alarm device including a second detection unit composed of a detector that detects a specific detection target and communicates with the alarm as the external device.
The alarm is configured to be powered by commercial power.
The detector is an alarm device that is configured to be powered by a battery and is configured to transmit a signal to the alarm when power supply is started.

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