JP6457291B2 - Disaster prevention equipment system - Google Patents

Description

  The present invention relates to a disaster prevention device system in which disaster prevention devices such as fire alarms and gas leak alarms installed in a house are connected to a central device via a wireless network.

  Disaster prevention equipment such as a fire alarm that detects an occurrence of a fire and generates an abnormal alarm and a gas leak alarm that detects a gas leak and generates an abnormal alarm are installed in the house. A disaster prevention equipment system in which these disaster prevention equipments are connected by a wireless network is known. In such a disaster prevention equipment system, for example, when a fire is detected by one fire alarm, it is possible to wirelessly transmit a fire detection signal to another fire alarm and generate an abnormal alarm also by another fire alarm It becomes.

  Residential disaster prevention equipment is mainly driven by batteries. Since the disaster prevention device is configured to be able to perform wireless communication in addition to monitoring a fire or the like, the battery may be consumed earlier than the life of the device. In this case, since a drop in battery voltage is detected, the disaster prevention device generates a battery low failure alarm when a voltage drop is detected. In addition to running out of the battery, the disaster prevention device may generate a failure alarm even if some kind of failure occurs in the disaster prevention device.

  A warning of failure occurrence such as a dead battery from a disaster prevention device is made by generating sound or light. It is not desirable for such a failure alarm to be generated at night because it disturbs sleep for the user. Therefore, it is conceivable that a failure alarm is not generated at night and a failure alarm is generated during the day.

  However, in that case, it is necessary to give the disaster prevention equipment a clock function. If the disaster prevention device is individually provided with a clock function, the battery life is affected by an increase in power consumption, and the number of parts increases, leading to an increase in cost. Even if an inexpensive watch is installed in a disaster prevention device, the clock error accumulates over a long period of time, and the time gradually shifts. is there.

  In this regard, for example, one of a plurality of disaster prevention devices is set as a master and the others are set as slaves, and time information is distributed from the master disaster prevention device to the slave disaster prevention device. By synchronizing periodically with the time information from the slave, it is possible to eliminate the need for the slave disaster prevention device to have a clock function. As such a disaster prevention equipment system, there exists a thing as listed in patent document 1, for example.

JP 2010-181921 A

  When setting a master and a slave in a disaster prevention device, the master disaster prevention device needs a clock function, so even if the same type of disaster prevention device (for example, a fire alarm), it does not have a clock function. It is necessary to make things differently. In the disaster prevention device having a clock function, the clock function and power for synchronizing the time are also required, so that battery consumption may be accelerated.

  The present invention has been made in view of the above problems, and an object of the present invention is to provide a disaster prevention device system that can change the operation related to a failure alarm according to a time zone without giving the disaster prevention device a clock function. And

In order to solve the above-mentioned problem, the disaster prevention device system according to the invention of claim 1 is characterized in that a plurality of disaster prevention devices and a central device that issue an abnormality alarm at the time of abnormality detection and a failure alarm at the time of failure of the own device are the first. A disaster prevention system connected wirelessly via a network,
The central device is connected to a device installed in a house via a second network, and at least one of the devices in the second network can transmit time information, and the time information is transmitted from the central device. Sent to the disaster prevention equipment,
The disaster prevention device is configured to change an operation state related to the failure alarm according to the received time information.

  According to the invention which concerns on Claim 1, based on the time information acquired from the apparatus in a 2nd network, the operation state regarding the failure alarm of a disaster prevention apparatus can be changed.

In the disaster prevention equipment system according to the invention of claim 2, the equipment capable of transmitting the time information transmits the first time information at a predetermined time in the night, and the second time information at a predetermined time in the daytime. Send
The disaster prevention device is configured to change an operation state related to the failure alarm, respectively, when the first time information is received and when the second time information is received.

  According to the invention which concerns on Claim 2, the operation state regarding the failure alarm of a disaster prevention apparatus can be changed by daytime and nighttime.

  Furthermore, the disaster prevention device system according to the invention of claim 3 is characterized in that the disaster prevention device has an alarm generation means for generating the failure alarm when a failure of its own device occurs, and after receiving the first time information, Until the second time information is received, the alarm generation means is in an operation state in which the failure alarm is not generated.

  According to the invention which concerns on Claim 3, it can prevent a user's sleep from being disturbed by not generating a failure alarm from a disaster prevention apparatus at night time zone.

  Furthermore, in the disaster prevention equipment system according to the invention of claim 4, the disaster prevention equipment has a failure of its own device between the time when the first time information is received and the time when the second time information is received. In this case, after the second time information is received, the alarm generation means generates the failure alarm.

  According to the invention according to claim 4, the failure alarm is not generated from the disaster prevention device during the night time period, but the failure alarm is generated at the time of the day time period, It becomes possible to find out about obstacles.

In the disaster prevention equipment system according to the invention of claim 5, the central device is connected to a home detection means capable of detecting the presence or absence of a person in the house, and the person in the house detected by the home detection means. Information on the presence or absence of
The disaster prevention device is configured to change an operation state related to the failure alarm according to the presence or absence of a person in the house detected by the at-home detection means.

  According to the fifth aspect of the present invention, it is possible to reduce useless trouble alarms by not generating trouble alarms when there is no person in the house.

  Moreover, the disaster prevention equipment system which concerns on invention of Claim 6 transmits the abnormality detection signal with respect to the apparatus connected with the said 2nd network, when the said central apparatus detects abnormality in the said disaster prevention apparatus. It is configured as a feature.

  According to the sixth aspect of the present invention, it is possible to perform a display for notifying the occurrence of abnormality in the devices in the second network.

  Furthermore, in the disaster prevention equipment system according to the invention of claim 7, when the central device detects a fault in the disaster prevention equipment, the central equipment acquires fault handling information from the disaster prevention equipment or from outside, and the fault handling information is 2 is configured to transmit to a device connected by the network of 2.

  According to the invention according to claim 7, even if a manual relating to the disaster prevention device is lost, the description etc. can be displayed on the device in the second network, and the failure of the disaster prevention device can be smoothly handled. It becomes possible to do.

Furthermore, in the disaster prevention equipment system according to the invention of claim 8, a plurality of disaster prevention equipment for issuing an abnormality alarm at the time of abnormality detection and a failure alarm at the time of failure of the own machine and the central unit are wirelessly connected via the first network. Disaster prevention equipment system,
The central device is connected to a device installed in a house through a second network, and can acquire time information from at least one of the devices in the second network,
The disaster prevention device transmits a request signal to the central device when a failure of its own device occurs, and the central device that has received the request signal indicates whether or not the failure alarm is generated according to the time information. The information is transmitted to the disaster prevention device.

  According to the invention which concerns on Claim 8, based on the time information acquired from the apparatus in a 2nd network, the operation | movement regarding the failure alarm of a disaster prevention apparatus can be varied.

  According to the disaster prevention equipment system according to the present invention, since the operation state regarding the failure alarm of the disaster prevention equipment is changed based on the time information acquired from the equipment in the second network, the disaster prevention equipment does not have a clock function. The operating state can be changed according to the time.

It is a whole block diagram of a disaster prevention equipment system. It is a block diagram of the apparatus installed in a house. It is a flowchart regarding the operation state change of the disaster prevention equipment according to a time zone. It is a flowchart of the failure alarm generation | occurrence | production of the fire alarm device accompanying the battery remaining charge falling. It is a whole block diagram of the disaster prevention equipment system in 2nd Embodiment. It is a block diagram of each apparatus which comprises the disaster prevention apparatus system in 2nd Embodiment. It is a flowchart which judges the presence or absence of the person in a house. It is a flowchart of the detection of whether it is sleeping. It is an operation | movement flowchart of the failure alarm in a fire alarm. It is a flowchart in the case of judging the possibility of a failure alarm in a central apparatus.

  Embodiments of the present invention will be described in detail with reference to the drawings. In the present embodiment, a disaster prevention system having a plurality of fire alarms 14 and a central device 10 installed in a house will be described. FIG. 1 shows an overall configuration diagram of the disaster prevention equipment system, and FIG. 2 shows a configuration diagram of each equipment constituting the disaster prevention equipment system.

(Installation of disaster prevention equipment and nature of alarm)
As shown in FIG. 1, the house 1 has a plurality of rooms 2, 3, and 4, and a fire alarm device 14 is installed as a disaster prevention device capable of detecting the occurrence of a fire and generating an abnormal alarm. The room 3 is provided with a fire receiver 15 as a disaster prevention device capable of generating an abnormality alarm by receiving a signal from the fire alarm device 14 when a fire occurs. The fire alarm device 14 and the fire receiver 15 can generate an abnormality alarm when a fire is detected and a failure alarm when a failure of the own device occurs. In the present embodiment, an abnormality refers to the occurrence of a fire, and a failure refers to an event that hinders the normal operation of the fire alarm 14 or the like, such as a decrease in the remaining battery level or a circuit failure.

  An abnormal alarm is an alarm when an abnormality such as a fire occurs, so it has urgency and must be generated regardless of the presence or absence of people in the house 1, but the fault alarm is a battery level indicator. It is a notification of a failure such as a drop, has no urgency, and has no significance unless there is a person in the house 1 noticing it. Since the failure alarm is not urgent, it does not necessarily have to be generated immediately when a failure occurs, and it can be generated during the daytime, not during nighttime sleeping. In addition, even when there is no person in the house 1, it is not always necessary to generate it immediately, and it can be generated after a person returns to the house 1. In this embodiment, the change of the operation state according to the time zone will be described.

(Configuration of each disaster prevention device)
As shown in FIG. 2, the fire alarm 14 of the present embodiment is a photoelectric sensor 14 a that can detect smoke generated during a fire, a plurality of fire alarms 14, a fire receiver 15, and a central device 10. Is generated by voice, a wireless communication unit 14b that transmits and receives information in a wireless network that is wirelessly connected, and an abnormal alarm when an abnormality is detected and a failure alarm when a failure occurs in the device itself Part 14c.

  The fire receiver 15 includes a wireless communication unit 15a that transmits and receives information, and an alarm generation unit 15b that generates an abnormal alarm by sound and light by receiving a signal from the fire alarm device 14. The alarm generation unit 15b also generates a failure alarm when a failure of the own device is detected. The fire alarm 14 and the fire receiver 15 are driven by batteries 14d and 15c.

  The radio communication unit 14b of the fire alarm 14 and the radio communication unit 15a of the fire receiver 15 are, for example, STD-30 (low power) known as a standard for a specific low power radio station in the 400 MHz band in Japan. It has a configuration conforming to the standard of wireless equipment for security system radio stations) or STD-T67 (standard for low power radio station telemeters, radio equipment for telecontrol and data transmission). However, it may conform to a standard other than this, or a configuration based on an original standard.

  Although the fire alarm device 14 is provided on the wall surface of each room in FIG. 1, it may be installed on the ceiling or the like. The principle of detecting a fire of the fire alarm 14 is to detect smoke in this embodiment, but may be any one of heat detection, flame detection, or a combination of these. .

(Other configuration of disaster prevention equipment system)
A central device 10 and a television 11 are further installed in the room 2 of the house 1. The central device 10 is connected to each fire alarm 14 in the house 1 through a first network, and is connected to the television 11 in the house 1 through a second network. In addition, although not only the television 11 but other household appliances are connected to a 2nd network, it abbreviate | omits in this embodiment. The central apparatus 10 is further connected to an external Internet network 5 and can transmit and receive information to and from the outside via the Internet network 5.

(Network configuration)
In order to perform wireless communication between the fire alarm 14 and the fire receiver 15, the first network employs a first communication method based on the standards of the wireless communication units 14b and 15a described above. The second network employs the second communication method in order to perform wireless communication between the central device 10 and the home appliances in the house 1. The second communication method is a communication method based on a predetermined standard different from the first communication method, and may be a communication method dedicated to home appliances or used in devices other than home appliances. A general-purpose communication method may be used.

(Configuration of central unit)
As shown in FIG. 2, the central apparatus 10 communicates with a control unit 10 a that performs communication control with each device, a wireless communication unit 10 b that performs communication with each device of the second network, and the Internet network 5. Internet communication unit 10c to perform. The television 11 includes at least a display unit 11a, a wireless communication unit 11b, and a clock unit 11c. Note that the television 11 and the central device 10 may be connected by wire, and in that case, the television 11 includes a wired communication unit (not shown).

  In addition, the central apparatus 10 includes a relay unit 10d that can transmit and receive information between the first network and the second network. The central device 10 is originally a device used for the second network, and as it is, information cannot be transmitted and received between the first network and the second network having different standards. By having it, the central device 10 can also be a component of the first network, which is a network of the fire alarm 14 and the fire receiver 15, and can exchange information between the two wireless networks. It becomes possible. The relay unit 10d also has a function of performing communication with each device of the first network.

(Operation of disaster prevention equipment when an abnormality is detected)
In any one of the fire alarms 14, when the sensor 14a detects the occurrence of a fire, the fire alarm 14 generates an abnormal alarm by voice from the alarm generator 14c. At the same time, the fire alarm device 14 transmits a fire occurrence signal to the other fire alarm device 14 and the fire receiver 15 from the wireless communication unit 14b, and the other fire alarm device 14 that has received the fire occurrence signal The fire receiver 15 that generates a sound abnormality alarm from the alarm generation unit 14c and receives the fire occurrence signal generates a light and sound abnormality alarm from the alarm generation unit 15b.

  In addition, the fire occurrence signal from the fire alarm 14 is also received by the central device 10. The central device 10 that has received the fire occurrence signal can transmit information indicating that a fire has occurred to an external security company or a fire department via the Internet network 5. The central device 10 can also transmit a fire occurrence signal to the devices of the second network. For example, the television 11 that has transmitted a fire occurrence signal to the television 11 and has received the fire occurrence signal can automatically display that a fire has occurred. In this manner, the user can more reliably grasp the occurrence of a fire by transmitting and receiving information across the first network and the second network.

(About fault alarm)
The fire alarm device 14 and the fire receiver 15 can detect that the remaining amount of the batteries 14d and 15c has decreased due to a decrease in the voltage level. The fire alarm device 14 and the fire receiver 15 that have detected that the remaining amount of the batteries 14d and 15c is low generate a failure alarm to that effect from the alarm generation units 14c and 15b. The operation of each device at this time will be described below. In addition, since the operation | movement in this case is the same in the fire alarm device 14 and the fire receiver 15, only the fire alarm device 14 is demonstrated here.

  First, when the fire alarm device 14 detects that the remaining amount of the battery 14d is low, the fire alarm device 14 immediately detects the first operation state in which a failure alarm is generated and the remaining amount of the battery 14d is low. In this case, it is possible to switch to the second operation state in which the failure alarm is not immediately generated and becomes a standby state for the failure alarm. Switching between these operating states is performed based on time information described later.

(Operation status switching for fire alarm failure alarm)
In FIG. 3, the flowchart of the operation state switching in the fire alarm 14 is shown. Time information refers to information corresponding to a time such as 7 am or 2 pm. In this embodiment, since the operation state of the fire alarm device 14 is switched twice at 7:00 am and 0:00 am, it is sufficient that at least two types of information can be transmitted and received between the devices.

  Acquisition of time information is performed in the television 11 connected to the second network. The television 11 may recognize the time from a received television broadcast signal, or may recognize the time from a built-in clock function. However, when the built-in clock function is used, it is possible that the time is gradually shifted. Therefore, it is desirable to correct the time every predetermined period from a television broadcast signal or the like.

  Here, the time information at midnight is the first time information, and the time information at 7:00 am is the second time information. As shown in FIG. 3, when the television 11 acquires the first time information (SA-1), the television 11 transmits the first time information to the central device 10 (SA-2). After that, when the television 11 acquires the second time information (SA-3), the television 11 transmits the second time information to the central device 10 (SA-4).

  The central apparatus 10 that has received the first time information from the television 11 (SB-1) transmits the first time information to the fire alarm device 14 in the first network (SB-2). Moreover, the central apparatus 10 which received 2nd time information from the television 11 (SB-3) transmits 2nd time information with respect to the fire alarm device 14 (SB-4).

  The fire alarm 14 that has received the first time information from the central device 10 (SC-1) switches from the first operating state to the second operating state (SC-2). Here, the first operation state of the fire alarm device 14 is an operation state in which a failure alarm is immediately generated from the alarm generation unit 14c when the remaining battery level is lower than a predetermined level. The second operation state is an operation state in which a failure alarm is not generated even when the remaining battery level is lower than a predetermined level. When the fire alarm device 14 receives the first time information, the fire alarm device 14 is switched to the second operation state. Therefore, until the second time information is received thereafter, the remaining battery level is low. Even if it is lower than the predetermined value, a failure alarm is not generated immediately.

  The fire alarm 14 that has received the second time information from the central device 10 (SC-3) switches from the second operation state to the first operation state (SC-4). That is, when the fire alarm device 14 receives the second time information, the fire alarm device 14 is switched to the first operation state. When the amount falls below a predetermined level, a fault alarm is immediately generated.

  It can be set from the television 11 what time the first time information and the second time information are respectively set. The television 11 is preliminarily provided with an application for setting the devices in the first network such as the fire alarm 14. This application can be operated by the remote controller of the television 11, and by setting the first time information and the second time information by this, when the television 11 reaches the set time, the first time information or the first time information is set. 2 time information is transmitted.

  Further, as another form of transmitting time information, the following can be considered. A request signal is transmitted from the fire alarm 14 to the central device 10 every predetermined time, the request signal is transmitted to a device of the second network, and the television 11 that has received the request signal receives the first time information or If the time set by the second time information is reached, one of the signals is transmitted. You may be comprised in this way.

(Fire alarm operation when battery level is low)
FIG. 4 shows a flow chart for generating a failure alarm of the fire alarm device 14 due to a decrease in the remaining battery level. First, the fire alarm 14 detects whether or not the remaining battery level has decreased (SD-1). If the remaining battery level has not decreased, the SD-1 step is repeated.

  If it is detected in step SD-1 that the remaining battery level is low, the fire alarm device 14 detects whether or not it is in the first operating state (SD-2). Here, in the first operation state, the fire alarm device 14 immediately generates a failure alarm from the alarm generation unit 14c (SD-3). In the case of the fire receiver 15, a failure alarm by light and sound is generated from the alarm generator 15 b.

  In step SD-2, if the fire alarm device 14 is not in the first operation state, that is, in the second operation state, the fire alarm device 14 does not generate a failure alarm and the second time information is displayed. It waits until it receives from the central apparatus 10 (SD-4). When the fire alarm device 14 receives the second time information from the central device 10, the fire alarm device 14 switches from the second operation state to the first operation state (SD-5). Then, a failure alarm is immediately generated from the alarm generator 14c (SD-6).

  Since the first time information is information corresponding to midnight and the second time information is information corresponding to 7:00 am, the second time after the fire alarm 14 receives the first time information. The time until the information is received is a midnight time zone. Even if the fire alarm 14 detects a low battery level during this midnight time period, it will not generate a fault alarm immediately, but will wait for 7:00 am before generating a fault alarm. It is possible to prevent a failure alarm from being issued during the time period. On the other hand, in a time zone other than midnight, when the fire alarm 14 detects a decrease in the remaining battery level, a failure alarm is immediately issued.

  Moreover, since the time information for changing the operation state according to the time is acquired from the television 11 which is a device in the second network, the fire alarm device 14 and the fire receiver 15 have a clock function. There is no need. Thereby, the increase in the number of parts of the fire alarm device 14 and the fire receiver 15 can be suppressed. Further, it is not necessary to make the fire alarm device 14 and the fire receiver 15 separately to those having a clock function and those not having a clock function, and all can be made common, so that further efficiency can be achieved.

  In the present embodiment, the first time information is information corresponding to midnight and the second time information is information corresponding to 7:00 am, but other times may be associated with each time information. In the present embodiment, when the fire alarm device 14 is in the second operation state, the failure alarm is generated immediately after the reception of the second time information. However, the present invention is not limited to this. A failure alarm may be generated when the condition is satisfied. Furthermore, in the present embodiment, the occurrence of a failure alarm for a low battery level has been described. However, the failure is not limited to a low battery level. The present invention can also be applied when it occurs.

  Further, when a failure alarm is generated from the fire alarm device 14, predetermined information may be displayed on the television 11. In this case, the fire alarm device 14 transmits the failure detection information to the central apparatus 10 through the first network when generating a failure alarm from the alarm generation unit 14c. At this time, the fire alarm device 14 also transmits to the central device 10 information related to the battery replacement procedure that is the failure handling information stored by itself. The central device 10 that has received the failure detection information and the failure handling information transmits them to the television 11 through the second network. The television 11 that has received the information from the central device 10 displays the battery replacement procedure information on the display unit 11a.

  The battery life of the fire alarm device 14 is long, and the instructions for the fire alarm device 14 are often lost at the time of battery replacement. The user can easily recognize that the failure alarm is due to a decrease in the remaining battery level, and can easily understand the battery replacement procedure. Further, the information on the battery replacement procedure, which is the failure response information, is not limited to the information transmitted from the fire alarm 14 to the central device 10, and the central device 10 that has received the failure detection information can transmit the predetermined external information via the Internet network 5. May be obtained from

(Overall configuration of the disaster prevention equipment system of the second embodiment)
Next, a second embodiment of the present invention will be described. FIG. 5 shows an overall configuration diagram of the disaster prevention equipment system in the second embodiment, and FIG. 6 shows a configuration diagram of each equipment constituting the disaster prevention equipment system in the second embodiment. As shown in FIG. 5, in the disaster prevention equipment system of this embodiment, a fire alarm device 14 is installed in each of rooms 2, 3, 4, a fire receiver 15 is installed in room 3, and a central device 10 is installed in room 2. And the point which the television 11 is installed is the same as that of 1st Embodiment. In the present embodiment, the abnormality includes not only the occurrence of a fire but also gas leakage.

  In the present embodiment, the fire extinguisher 12 is further installed in the rooms 2 and 4, the human sensor 16 is installed in each of the rooms 2 and 4, and the gas leak alarm 13 is installed in the room 3. Also, a recorder 24 is installed in the room 2, a lighting device 23 is installed in each of the rooms 2, 3 and 4, a stove 22 is installed in the room 3, and a gas meter 21 is installed outside the room.

(Configuration of each disaster prevention device)
The fire extinguisher 12 is for extinguishing fire by injecting it toward the flame when a fire occurs. In the present embodiment, the fire extinguisher 12 is further provided with a wireless communication unit 12a, Wireless communication is possible. The wireless communication unit 12a is driven by the battery 12b.

  The gas leak alarm 13 detects a gas by the sensor 13a when gas is leaking, generates an abnormality alarm, and further, a radio communication unit 13b that performs radio communication with the central apparatus 10, and a gas It has an alarm generation unit 13c that generates a leakage alarm and a failure alarm for a low battery level, and a battery 13d that supplies electric power.

  The human sensor 16 includes a sensor 16a that detects infrared rays emitted by humans, and can detect whether or not there is a person in the room. Further, the human sensor 16 can wirelessly transmit the detection result of the presence / absence of a person to the central apparatus 10 using the wireless communication unit 16b.

  In the present embodiment, the fire alarm device 14, the fire receiver 15, the human sensor 16, the fire extinguisher 12, and the gas leak alarm device 13 constitute a first network with the central device 10.

(Configuration of each home appliance)
The recorder 24 includes a wireless communication unit 24a capable of wireless communication with the central device 10 and a clock unit 24b. The recorder 24 has a function of recording a television broadcast. In this embodiment, the recorder 24 can be used as a device having a clock function instead of the television 11.

  The lighting device 23 installed in each of the rooms 2, 3 and 4 is provided with a wireless communication unit 23a capable of wireless communication with the central apparatus 10. The lighting device 23 can wirelessly transmit information on the lighting on / off state to the central device 10.

  The gas meter 21 measures the amount of gas used in the house 1, and includes a measurement unit 21 a that performs the measurement and a wireless communication unit 21 b that wirelessly transmits the measurement result to the central device 10. Yes. The stove 22 is installed in the room 3 that is a kitchen and is used for cooking, and has a wireless communication unit 22 a that wirelessly transmits the use state to the central device 10.

  In the present embodiment, the television 11, gas meter 21, stove 22, lighting device 23, and recorder 24 constitute a second network with the central device 10.

(Fault alarm in the second embodiment)
In the disaster prevention equipment system of this embodiment, the fire alarm device 14, the fire receiver 15, the fire extinguisher 12, and the gas leak alarm device 13 have batteries 14d, 15c, 12b, and 13d, respectively. A fault alarm is generated when the remaining battery level is low. And in each apparatus, it is possible to prevent a failure alarm from being generated in the midnight time zone by using the clock function of the television 11 or the recorder 24. In addition, the operation state can be changed according to conditions such as the presence or absence of a person in the house 1 and whether or not the person is asleep. The operation will be described below.

(Determination of the presence or absence of people in the house)
The presence / absence of a person in the house 1 can be detected by a human sensor 16 as at-home detection means. Moreover, the gas meter 21 and the stove 22 can also be used as at-home detection means. The gas meter 21 and the stove 22 are used to determine that there are people in the house 1. For example, when the amount of gas used detected by the measuring unit 21a of the gas meter 21 is greater than or equal to a predetermined amount, it can be determined that there is a person in the house 1. Even when the stove 22 is in use, it can be determined that there is a person in the house 1.

  The presence or absence of a person in the house 1 can be detected more accurately by using not only one device but also a plurality of devices. For example, the operation of the central apparatus 10 that receives information on each device can be a flow as shown in FIG. First, it is detected whether or not the stove 22 is used (SE-1), and if it is used, it is determined that it is at home (SE-2). When the stove 22 is not used, it is detected whether or not the amount of gas used detected by the gas meter 21 is greater than or equal to a predetermined value (SE-3). -4). If the amount of gas used is less than the predetermined amount, the presence sensor 16 detects whether there is a person (SE-5). If the presence sensor 16 detects that there is a person, it is determined that the person is at home (SE-6). If the presence sensor 16 detects that there is no person, it is determined that the person is absent (SE-7). The presence or absence of a person in the house 1 may be determined by the central device 10, but information from each device is acquired by the first network device such as the fire alarm 14 through the central device 10. The determination may be made in one network device.

(Judgment of sleeping in the house)
Whether or not a person in the house 1 is sleeping can be detected by the clock function of the television 11 or the recorder 24 and the lighting device 23. Here, similarly to the first embodiment, the television 11 or the recorder 24 sends the first time information and the second time information to the central device 10 at predetermined times, for example, midnight and 7:00 pm, respectively. Shall be transmitted. In this case, the detection as to whether or not the central device 10 is sleeping can be a flow as shown in FIG.

  First, the central apparatus 10 detects whether or not it is after the reception of the first time information and before the reception of the second time information, that is, in the midnight time zone (SF-1). If it is not in the midnight time zone, it is determined that the person is not in a sleeping state, so the flow is terminated as it is (SF-2). If it is a late-night time zone in SF-1, the usage state of the lighting device 23 is further detected (SF-3), and if at least one lighting device 23 is on, the user has not gone to bed. The flow is terminated (SF-4). When all the lighting devices 23 are off in SF-3, it can be determined that the person is sleeping (SF-5). Whether the person in the house 1 is sleeping or not may be determined by the central device 10, but information from each device is obtained from the first network device such as the fire alarm 14 by the central device 10. It is also possible to obtain the information through the first network device and make a determination in the first network device.

(Operation for generating a fault alarm in the second embodiment)
FIG. 9 shows an operation flow of the failure alarm in the fire alarm device 14 to which these determinations are added. First, the fire alarm 14 detects whether or not the remaining battery level has decreased (SG-1). If the remaining battery level has not decreased, the step SG-1 is repeated.

  If it is detected in step SG-1 that the remaining battery level is low, the presence or absence of a person in the house 1 is determined (SG-2). The determination here is performed according to the flow of FIG. 7, and the fire alarm 14 may receive the information of the determination performed by the central device 10, or the fire alarm 14 receives the necessary information. It may be determined by itself.

  When it is determined in SG-2 that there is no person in the house 1, the fire alarm device 14 enters the second operation state regardless of the operation state of the fire alarm device 14 (SG-3). That is, the operation state immediately does not generate a failure alarm. Subsequently, the flow of FIG. 7 is repeated every predetermined time (SG-4), and when it is determined that there is a person, that is, it is determined that the person has returned home, the fire alarm device 14 switches to the first operation state (SG -5) A failure alarm is generated (SG-6).

  When it is determined in SG-2 that there is a person in the house 1, it is next detected whether or not the fire alarm 14 is in the first operating state (SG-7). Here, in the first operation state, the fire alarm device 14 immediately generates a failure alarm from the alarm generation unit 14c (SG-8).

  If the fire alarm 14 is in the second operating state in SG-7, it is further determined whether or not a person in the house 1 is sleeping (SG-9). This determination is performed in the flow of FIG. 8, and the fire alarm 14 may receive the information of the determination made in the central device 10, or the fire alarm 14 receives the necessary information. You may make it judge by itself.

  If it is not determined that the patient is sleeping at SG-9, the fire alarm device 14 switches to the first operation state (SG-10), and a failure alarm is generated from the alarm generator 14c (SG-11). If it is determined that the patient is sleeping at SG-9, the fire alarm device 14 further waits until the second time information is received from the central device 10 (SG-12). The second operation state is switched to the first operation state (SG-13). Then, a failure alarm is immediately generated from the alarm generation unit 14c (SG-14).

  In this way, in the first network device, based on the information from the other devices of the first network and the second network device, the presence or absence of a person in the house 1 and the sleeping state are determined. It becomes possible to generate a failure alarm more appropriately. Specifically, when there is no person in the house 1, no one notices even if a failure alarm is generated, so that the failure alarm can be generated after returning home. Further, even in the late-night time zone, a failure alarm can be generated if the user is not yet sleeping, and if the user is asleep, the failure alarm can be generated waiting for the next morning.

  Here, the operation of the fire alarm 14 for the fault alarm has been described, but the same applies to the fire receiver 15, the fire extinguisher 12, and the gas leak alarm 13.

  Further, in the disaster prevention device in the first network such as the fire alarm device 14, instead of switching the operation state related to the failure alarm based on the first time information and the second time information, each disaster prevention device in the central device 10 It may be determined which operation is performed. A flowchart in this case is shown in FIG. Here, the operation of the fire alarm device 14 is shown, but the same applies to the fire receiver 15, the fire extinguisher 12, and the gas leak alarm device 13.

  First, the fire alarm device 14 detects whether or not a failure has occurred in the own device such as a decrease in the remaining battery level (SH-1). When the occurrence of a failure is detected, a request signal is transmitted to the central apparatus 10 (SH-2). The central apparatus 10 that has received the request signal detects the presence or absence of a person according to the flow of FIG. 7 (SH-3), and if it is absent, transmits information indicating that no alarm is available to the fire alarm 14 (SH-). 4). The fire alarm 14 that has received the information indicating that the alarm is disabled does not generate a failure alarm. Thereafter, the central apparatus 10 repeats the flow of FIG. 7 at predetermined time intervals (SH-5), and when it is determined that the user is going home, transmits information indicating that an alarm is possible to the fire alarm device 14 (SH-6). The fire alarm 14 that has received this information generates a failure alarm.

  When it is determined that the user is at home in the step SH-3, the central apparatus 10 determines whether the time is after the first time and before the second time (SH-7). The time is acquired from a device in the second network such as the central device 10 itself or the television 11. If the time is not within the time determined by SH-7, information indicating that an alarm is possible is transmitted from the central apparatus 10 (SH-8). If the time is within the time determined in SH-7, it is further determined whether or not you are sleeping according to the flow of FIG. 8 (SH-9). Is transmitted from the central apparatus 10 (SH-10).

  If it is determined in step SH-9 that the user is sleeping, the central apparatus 10 transmits information indicating that the alarm is disabled (SH-11). Then, it waits until it becomes 2nd time (SH-12), and if it becomes 2nd time, the central apparatus 10 will transmit the information to the effect of an alarm (SH-13). Even with such a flow, the operation relating to the failure alarm can be changed according to the time zone without providing the disaster prevention device with a clock function.

  Although the embodiment of the present invention has been described above, the application of the present invention is not limited to this embodiment, and can be applied in various ways within the scope of its technical idea. For example, in these embodiments, the first time information and the second time information are transmitted using the clock function of the television 11 or the recorder 24 that is a device of the second network. 10 may have a clock function, and the central device 10 may transmit the first time information and the second time information.

  Further, the devices in the first network such as the fire alarm device 14 may be provided with an internal clock configuration, and the function related to the failure alarm may be switched using the function. In this case, the internal clock has a large error, and the time deviation is accumulated by using the internal clock for a long time. Therefore, the correction can be performed as follows. First, the fire alarm 14 transmits a request signal to the central apparatus 10 at predetermined intervals, for example, every day, every week, or every other month. The central device 10 that has received the request signal acquires an accurate time from its own clock function or a clock function such as the television 11 in the second network, and transmits information on the time to the fire alarm device 14. The fire alarm 14 that has received the time information corrects it based on the time information at which its own internal clock is received. As described above, by periodically synchronizing, the operation state related to the failure alarm can be switched using the internal clock of the fire alarm device 14.

DESCRIPTION OF SYMBOLS 1 Housing 2 1st room 3 2nd room 4 3rd room 5 Internet network 10 Central apparatus 10a Control part 10b Wireless communication part 10c Internet communication part 10d Relay part 11 Television 11a Display part 11b Wireless communication part 11c Clock part 12 Fire extinguisher 13 Gas leak alarm 14 Fire alarm 14a Sensor 14b Wireless communication unit 14c Alarm generating unit 14d Battery 15 Fire receiver 16 Human sensor 21 Gas meter 22 Stove 23 Lighting equipment 24 Recorder

Claims (8)

A disaster prevention device system in which a plurality of disaster prevention devices and a central device that issue an abnormality alarm at the time of abnormality detection and a failure alarm at the time of failure of the aircraft are wirelessly connected via a first network,
The central device is connected to a device installed in a house via a second network, and at least one of the devices in the second network can transmit time information, and the time information is transmitted from the central device. Sent to the disaster prevention equipment,
The disaster prevention device system changes an operation state related to the failure alarm according to the received time information. The device capable of transmitting the time information transmits first time information at a predetermined time in the night, and transmits second time information at a predetermined time in the daytime.
2. The disaster prevention device according to claim 1, wherein the disaster prevention device changes an operation state related to the failure alarm when the first time information is received and when the second time information is received. Equipment system.   The disaster prevention device has an alarm generation means for generating the failure alarm when a failure of its own device occurs, and until receiving the second time information after receiving the first time information, The disaster prevention equipment system according to claim 2, wherein an operation state in which the failure alarm is not generated from the alarm generation means is established.   The disaster prevention device, after receiving the second time information, when a failure of the own device occurs between receiving the first time information and receiving the second time information. The disaster prevention system according to claim 3, wherein the failure alarm is generated by the alarm generation means. The central device is connected to a home detection means capable of detecting the presence or absence of a person in the house, and transmits information on the presence or absence of a person in the house detected by the home detection means to the disaster prevention device,
The said disaster prevention apparatus changes the operation state regarding the said fault alarm according to the presence or absence of the person in the house detected by the said home detection means, The disaster prevention of any one of Claims 1-4 characterized by the above-mentioned. Equipment system.   The said central apparatus transmits an abnormality detection signal with respect to the apparatus connected with the said 2nd network, when abnormality is detected with the said disaster prevention apparatus, The any one of Claims 1-5 characterized by the above-mentioned. The disaster prevention equipment system according to item.   When the central device detects a failure in the disaster prevention device, the central device acquires failure response information from the disaster prevention device or from the outside, and transmits the failure response information to a device connected through the second network. The disaster prevention equipment system according to any one of claims 1 to 6. A disaster prevention device system in which a plurality of disaster prevention devices and a central device that issue an abnormality alarm at the time of abnormality detection and a failure alarm at the time of failure of the aircraft are wirelessly connected via a first network,
The central device is connected to a device installed in a house through a second network, and can acquire time information from at least one of the devices in the second network,
The disaster prevention device transmits a request signal to the central device when a failure of its own device occurs, and the central device that has received the request signal indicates whether or not the failure alarm is generated according to the time information. A disaster prevention system that transmits to the disaster prevention equipment.

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