JP2016151972A - Fire notification system and external defibrillator - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a fire notification system and external defibrillator that allow persons present in a monitor area to be notified of a state of the external defibrillator, and allow compactification of an installation space to be attained.SOLUTION: A fire notification system is the fire notification system that detects a fire in a monitor area to set off the alarm, and comprises: a display device 60 that displays fire information by means of a display lamp 61; an AED 40 that implements defibrillation; and a radio communication unit 52 that implements radio communication with the AED 40. The AED 40 is provided with a determination unit 48a that determines a state of the AED 40; and a radio communication unit 44b that wirelessly implements communication of a signal including state information indicative of a state of the AED 40 with the radio communication unit 52 on the basis of a determination result of the determination unit 48a. When the signal including the state information transmitted from the radio communication unit 44b is received via the radio communication unit 52, the display device 60 is configured to cause the display lamp 61 to output the state information.SELECTED DRAWING: Figure 3

Description

  The present invention relates to a fire alarm system and an automatic external defibrillator.

  Conventionally, in various buildings, an automatic extracorporeal system is used to return the heart to a normal rhythm by electric shock (so-called defibrillation) for people whose heart has become unable to beat normally. A defibrillator (hereinafter referred to as “AED”) is installed. The AED is installed in a building in various forms, and is accommodated in, for example, a dedicated storage box provided in the building (see, for example, Patent Document 1).

JP 2010-194030 A

  Here, in using or managing the AED, various measures are taken depending on the state of the AED. For example, in a state where an AED is used to save a person whose heart cannot be beaten normally, a third party other than the user of the AED (for example, use of the AED) Disaster prevention center personnel, etc., who are away from the person) will take measures such as supporting the lifesaving activities. Therefore, in order to perform such measures quickly, a technique that can notify the person in the building of the state of the AED is desired. However, in the above conventional technique, the storage box merely stores the AED, and the state of the AED cannot be notified. Therefore, since the person in the building could not grasp the state of the AED, there was a problem that it was difficult to quickly take necessary measures according to the state of the AED.

  On the other hand, in order to solve such a problem, it is conceivable to provide output means for outputting the state of the AED in the storage box. However, since it is necessary to secure a space for providing the output means, there is a problem that it is difficult to reduce the installation space.

  The present invention has been made in view of the above, and is capable of notifying a person in a monitoring area of a building of the state of an automatic external defibrillator and reducing the installation space. It is an object to provide a fire alarm system and an automatic external defibrillator that can be used.

  In order to solve the above-described problems and achieve the object, the fire alarm system according to claim 1 is a fire alarm system that detects a fire in a monitoring area and issues an alarm, and fire information indicating a fire alarm A fire information output device for outputting the output by the output means, an automatic external defibrillator for performing defibrillation, and a first wireless communication means for performing wireless communication between the automatic external defibrillator, The automatic external defibrillator includes a determination unit that determines a state of the automatic external defibrillator, and a state of the automatic external defibrillator based on a determination result of the determination unit. Second wireless communication means for wirelessly communicating a signal including state information indicating to the first wireless communication means, wherein the fire information output device receives the state information transmitted from the second wireless communication means. A signal containing is received via the first wireless communication means. If the, to output the status information to the output unit.

  The fire alarm system according to claim 2 is the fire alarm system according to claim 1, wherein the automatic external defibrillator includes a use state of the automatic external defibrillator, The second wireless communication means of the external defibrillator is in use when the automatic external defibrillator is in use when the determination means determines that the automatic external defibrillator is in use. A signal including the state information indicating that the communication is performed is wirelessly communicated to the first wireless communication means.

  The fire alarm system according to claim 3 includes a failure state of the automatic external defibrillator as the state of the automatic external defibrillator in the fire alarm system according to claim 1 or 2, The second wireless communication means of the automatic external defibrillator is configured such that, when the determination means determines that the automatic external defibrillator is in a failure state, the automatic external defibrillator is A signal including the state information indicating a failure state is wirelessly communicated to the first wireless communication means.

  The fire alarm system according to claim 4 is the fire alarm system according to any one of claims 1 to 3, wherein the state of the automatic external defibrillator is the state of the automatic external defibrillator. The second wireless communication means of the automatic external defibrillator is determined to be in a use-necessary state by the determination means, including a use-needed state that requires use. In this case, a signal including the state information indicating that the automatic external defibrillator is in a use-necessary state is wirelessly communicated to the first wireless communication means.

  The fire alarm system according to claim 5 is the fire alarm system according to any one of claims 1 to 4, further comprising a display device that displays the fire information by a display means as the fire information output device, The display device causes the display unit to display the state information when a signal including the state information transmitted from the second wireless communication unit is received via the first wireless communication unit.

  The fire alarm system according to claim 6 is the fire alarm system according to any one of claims 1 to 5, wherein the fire information is output as an alarm sound by an alarm sound output means as the fire information output device. When the signal including the state information transmitted from the second wireless communication unit is received via the first wireless communication unit, the acoustic device outputs the state information as the warning sound. Let the means output.

  The fire alarm system according to claim 7 is the fire alarm system according to any one of claims 1 to 6, wherein the automatic external defibrillator is configured to stop communication of a signal including the state information. Communication stop operation means for receiving the signal, and when the second wireless communication means of the automatic external defibrillator receives an instruction to stop communication of the signal including the state information via the communication stop operation means Then, communication of the signal including the state information is stopped.

  The fire alarm system according to claim 8 is the fire alarm system according to any one of claims 1 to 7, wherein the automatic external defibrillator is different from the automatic external defibrillator. A voice input means for inputting voice, a voice output means for outputting voice, a user of the automatic external defibrillator, and the other equipment, which are connected so as to be able to communicate with each other. Call processing means for performing processing related to a phone call made by voice.

  The fire alarm system according to claim 9 is the fire alarm system according to claim 8, wherein the automatic external defibrillator is connected to the other device so as to be able to communicate with each other. An image pickup means for picking up an image around the automatic external defibrillator or an image display means for displaying an image, and the call processing means of the automatic external defibrillator is provided by the image pickup means. A signal including a captured image is communicated to the other device via the second wireless communication unit, or a signal including an image transmitted from the other device is received via the second wireless communication unit. When it is done, the image is displayed on the image display means.

  The automatic external defibrillator according to claim 10 is an automatic external defibrillator that performs defibrillation, and includes a determination unit that determines a state of the automatic external defibrillator, A second wireless communication unit configured to perform wireless communication with the wireless communication unit, and based on a determination result of the determination unit, a signal including state information indicating a state of the automatic external defibrillator And a second wireless communication means for transmitting to the fire information output device for outputting fire information indicating fire notification via the wireless communication means.

  According to the fire alarm system of claim 1, the automatic external defibrillator receives a signal including state information indicating the state of the automatic external defibrillator based on the determination result of the determination unit. A second wireless communication means for wirelessly communicating with the first wireless communication means, and the fire information output device receives the signal including the state information transmitted from the second wireless communication means via the first wireless communication means. If the automatic external defibrillator is used at a location away from the first wireless communication means, the status information is output from the automatic external defibrillator. The fire information output device can receive the signal including the state information thus obtained via the first wireless communication means, and the state information can be presented to the person in the monitoring area. As a result, people in the monitoring area can grasp the state of the automatic external defibrillator and can take necessary measures according to the state of the automatic external defibrillator more quickly than the conventional technology. It becomes. In addition, since the fire information and state information are output by the output means of the fire information output device, for example, compared with the case where output means for outputting only fire information and output means for outputting only state information are provided respectively. Thus, the installation space can be reduced and the installation space can be made compact.

  According to the fire alarm system of claim 2, when the second wireless communication means determines that the automatic external defibrillator is in use by the determination means, the automatic external defibrillator Since the signal including the state information indicating that the device is in use is wirelessly communicated to the first wireless communication means, it indicates to the person in the monitoring area that the automatic external defibrillator is in use. State information can be presented. This allows people in the surveillance area to know that the automated external defibrillator is in use, and to perform lifesaving activities for people whose heart has become unable to beat normally In addition, when an automatic external defibrillator is used, the user of the automatic external defibrillator can easily receive life support from a third party other than the user quickly. .

  According to the fire alarm system of claim 3, when the second wireless communication means determines that the automatic external defibrillator is in a failure state by the determination means, the automatic external defibrillator Since the signal including the state information indicating that is in a failure state is wirelessly communicated to the first wireless communication means, it indicates to the person in the monitoring area that the automatic external defibrillator is in the failure state. State information can be presented. Thereby, a person in the monitoring area can grasp that the automatic external defibrillator is in a failure state, and can quickly inspect and repair the automatic external defibrillator.

  According to the fire alarm system of claim 4, when the second wireless communication means determines that the automatic external defibrillator is in a use-necessary state by the determination means, the automatic external defibrillation is performed. Since a signal including state information indicating that the device is in a use-needed state is wirelessly communicated to the first wireless communication means, the automatic external defibrillator is in a use-needed state for a person in the monitoring area State information indicating the effect can be presented. Thereby, the person in the monitoring area can grasp that the automatic external defibrillator is in a use-needed state, and can use the automatic external defibrillator quickly.

  According to the fire alarm system of the fifth aspect, when the display device receives a signal including the state information transmitted from the second wireless communication unit via the first wireless communication unit, the state information is displayed. Since the information is displayed on the display means, the status information can be displayed on the display means and presented to the person in the monitoring area, and the status information can be easily and reliably transmitted to the person in the monitoring area.

  According to the fire alarm system of the sixth aspect, when the acoustic device receives a signal including the state information transmitted from the second wireless communication unit via the first wireless communication unit, the state information is displayed. Since the alarm sound output means outputs, the state information can be presented through hearing to the person in the monitoring area. Therefore, when the person in the monitoring area is at a position where the output means cannot be seen, or when the output means can be seen, it is difficult to see the information displayed on the output means. However, it is possible to quickly convey the state information.

  According to the fire alarm system of claim 7, when the second wireless communication means of the automatic external defibrillator receives an instruction to stop communication of a signal including state information via the communication stop operation means In addition, since the communication of the signal including the state information is stopped, the state information is output by the output means of the fire information output device when the administrator of the fire alarm system inspects the automatic external defibrillator. Therefore, although the automatic external defibrillator is not used, it is possible to prevent the status information from being erroneously output.

  According to the fire alarm system according to claim 8, the automatic external defibrillator includes a voice input means for inputting voice, a voice output means for outputting voice, and a user of the automatic external defibrillator. Call processing means for performing processing related to a call performed by voice between the user of the external device and the other device, so that the user of the external external defibrillator and the user of the other device The user of the automatic external defibrillator can receive advice on the use of the automatic external defibrillator from the user of another device.

  According to the fire alarm system of claim 9, the call processing means of the automatic external defibrillator sends the signal including the image picked up by the image pickup means to another device via the second wireless communication means. When a signal including an image transmitted from another device is received via the second wireless communication unit, the image is displayed on the image display unit. Therefore, the automatic external defibrillator Images can be exchanged between users and users of other devices. Therefore, for example, a user of another device can accurately grasp the situation around the automatic external defibrillator based on the image received from the automatic external defibrillator. Alternatively, the user of the automatic external defibrillator can accurately grasp advice on the use of the automatic external defibrillator based on the image received from another device.

  The automatic external defibrillator according to claim 10 is the second wireless communication means for performing wireless communication with the first wireless communication means, and based on the determination result of the determination means, Since the second wireless communication means for transmitting the signal including the state information indicating the state of the defibrillator to the fire information output device for outputting the fire information indicating the fire notification via the first wireless communication means is provided. Even if the automatic external defibrillator is used at a location away from the first wireless communication means, a signal including status information can be transmitted to the fire information output device via the first wireless communication means. It is possible to present the status information to the person in the room. As a result, people in the monitoring area can grasp the state of the automatic external defibrillator and can take necessary measures according to the state of the automatic external defibrillator more quickly than the conventional technology. It becomes. In addition, since the fire information and state information are output by the output means of the fire information output device, for example, compared with the case where output means for outputting only fire information and output means for outputting only state information are provided respectively. Thus, the installation space can be reduced and the installation space can be made compact.

It is the schematic which shows the structure of the fire alarm system which concerns on Embodiment 1 of this invention. It is a front view of a composite alerting | reporting apparatus. It is the block diagram which showed the electrical structure of the composite alerting | reporting apparatus. It is the block diagram which showed the electrical structure of the receiver. It is a flowchart of the fire alerting | reporting process regarding a sensor or a transmitter. It is a flowchart of the fire alerting | reporting process regarding a display apparatus or an audio apparatus. It is a flowchart of the use condition alerting | reporting process regarding AED. It is a flowchart of the use condition alerting | reporting process regarding a display apparatus or an audio apparatus. It is a flowchart of the failure state alerting | reporting process regarding AED. It is a flowchart of the failure state alerting | reporting process regarding a display apparatus or an audio apparatus. It is a flowchart of the use required state alerting | reporting process regarding AED. It is a flowchart of a use required state alerting | reporting process regarding a display apparatus or an audio apparatus. It is the schematic which shows the structure of the fire alarm system which concerns on Embodiment 2. FIG. It is the block diagram which showed the electrical structure of the composite alerting | reporting apparatus. It is the block diagram which showed the electrical structure of the receiver. It is a flowchart of the fire alerting | reporting process regarding a sensor or a transmitter. It is a flowchart of the fire alerting | reporting process regarding a display apparatus or an audio apparatus.

  Embodiments of a fire alarm system and an automatic external defibrillator according to the present invention will be described below in detail with reference to the accompanying drawings. First, [I] the basic concept of the embodiment will be described, then [II] the specific content of the embodiment will be described, and finally, [III] a modification to the embodiment will be described. However, the present invention is not limited to the embodiments.

[I] Basic Concept of Embodiment First, the basic concept of the embodiment will be described. Embodiments generally relate to a fire alarm system that detects and alerts a fire in a monitoring area. The control method of this fire alarm system is arbitrary, for example, a method of performing response control between a terminal device such as a sensor and a receiver by a polling / selecting method (so-called R-type method), Including a method (so-called P-type method) in which a signal line is drawn for each line and the receiver receives a report from the terminal device based on the opening and closing of the contact of the terminal device connected to the line. Note that the installation target and application target of the fire alarm system according to the embodiment are arbitrary, and can be applied to, for example, an apartment house, an office building, or a commercial facility. Hereinafter, in Embodiment 1, the case where the fire alarm system is an R-type system applied to an apartment house (hereinafter simply referred to as “building”) will be described, and in Embodiment 2, the fire alarm system will be described. Is a case of a P-type system applied to a building.

[II] Specific Contents of Embodiment Next, specific contents of the embodiment will be described.

[Embodiment 1]
First, the fire alarm system according to Embodiment 1 will be described. In the first embodiment, the control method of the fire alarm system is an R-type method.

(Constitution)
First, the configuration of the fire alarm system according to Embodiment 1 will be described. FIG. 1 is a schematic diagram showing a configuration of a fire alarm system according to Embodiment 1 of the present invention. As shown in FIG. 1, the fire alarm system 1 includes a sensor 10, a composite alarm device 20, a receiver 80, and a notification device 90. The sensor 10 is arranged on the ceiling or wall of the building, and the composite notification device 20 and the receiver 80 are arranged on the wall of the building. Among these, the sensor 10 and the composite alerting | reporting apparatus 20 are arrange | positioned 1 unit | set or multiple units | sets for every floor so that the legal installation space | interval may be satisfy | filled. In addition, one receiver 80 and one notification device 90 are arranged in a building, for example, in a manager room of the building.

  The connection form of these devices is set as shown below. Specifically, since a method in which each device is connected by a common signal line (so-called R-type method) is adopted, the sensor 10, a transmitter 30 described later, an AED 40 described later, a relay device 50 described later, The notification device 90 is connected to the receiver 80 via the first wiring 2. In addition, a display device 60 described later is connected to the receiver 80 via the second wiring 3, and an acoustic device 70 described later is connected to the receiver 80 via the third wiring 4. With such a connection, each of the sensor 10, the transmitter 30 described later, the AED 40 described later, the relay device 50 described later, the display device 60 described later, the acoustic device 70 described later, and the notification device 90 connected to the receiver 80. Output from the receiver 80 to the sensor 10, a transmitter 30 to be described later, an AED 40 to be described later, a relay device 50 to be described later, a display device 60 to be described later, an acoustic device 70 to be described later, and a notification device 90. (Ie, each of the first wiring 2, the second wiring 3, and the third wiring 4 functions as a signal line and also functions as a power supply line).

(Configuration-sensor)
Next, the configuration of the sensor 10 will be described. The sensor 10 is a wired fire notification terminal that transmits a fire signal for notifying a fire or a fire recovery signal for notifying a recovery from a fire. The sensor 10 includes a sensor unit, a communication unit, and a control unit (all not shown). The sensor 10 can be constituted by, for example, a well-known wired sensor or the like, and thus detailed description thereof is omitted.

  The sensor unit is detection means for detecting temperature, smoke density, and the like. The communication unit is a communication unit that communicates with the receiver 80 via the first wiring 2. The control unit is a control unit that controls each unit of the sensor 10. Specifically, the control unit is a CPU, various programs that are interpreted and executed on the CPU (such as a basic control program such as an OS, or an OS that is activated and specified on the OS). And an internal memory such as a RAM for storing programs and various data (including a control unit for the transmitter 30 described later and a control unit for the AED 40 described later) 48, control unit 53 of relay device 50 described later, control unit 63 of display device 60 described later, control unit 73 of acoustic device 70 described later, control unit 87 of receiver 80 described later, and control of notification device 90 described later. The same shall apply to the part).

(Configuration-combined notification device)
Next, the configuration of the composite notification device 20 will be described. FIG. 2 is a front view of the composite notification device 20. FIG. 3 is a block diagram showing an electrical configuration of the composite notification device 20. The composite notification device 20 is a device that combines a device for notifying a fire and a device for treating a person. As shown in FIGS. 2 and 3, the composite notification device 20 includes a transmitter 30, an AED 40, a relay device 50, and a display inside a housing 21 provided in a building (that is, in a monitoring area). The device 60 and the acoustic device 70 are integrally accommodated. In addition, the connection form of the devices constituting the composite notification device 20 is arbitrary, but in the first embodiment, the relay device 50, the display device 60, and the acoustic device 70 each connect the fourth wiring 5. The AED 40 and the relay device 50 are connected so as to be capable of wireless communication. With such a connection, communication can be performed between the relay device 50 and each of the display device 60 and the acoustic device 70, and communication can be performed between the AED 40 and the relay device 50.

(Configuration-Composite alarm device-Housing)
The casing 21 is a basic structure of the composite notification device 20, and is a protection means that protects the transmitter 30, the AED 40, the relay device 50, the display device 60, and the acoustic device 70 from the outside. The casing 21 is a substantially box-shaped body made of, for example, a metal material. Specifically, the housing 21 is a substantially box-shaped base portion 22a with one side surface (for example, the front surface or the like) open, and includes a transmitter 30, an AED 40, a relay device 50, a display device 60, and an acoustic device. 70, an upper front panel portion 22b that substantially covers the upper portion of the base portion 22a from its open surface side, and a lower front panel portion that substantially covers the lower portion of the base portion 22a from its open surface side. 22c, and the upper front panel portion 22b and the lower front panel portion 22c are fixed to the base portion 22a by a fitting structure or a fixture (or the upper front panel portion 22b and The lower front panel portion 22c may be formed integrally with the base portion 22a).

  Here, in this base part 22a, each part which comprises each of the transmitter 30, the relay apparatus 50, the display apparatus 60, and the acoustic apparatus 70 is being fixed above the said base part 22a, and the said base part Below the 22a, each part constituting the AED 40 is fixed. Moreover, the opening part in which the 1st wiring 2, the 2nd wiring 3, and the 3rd wiring 4 connected to the transmitter 30, AED40, the relay apparatus 50, the display apparatus 60, or the acoustic apparatus 70 were formed in the base part 22a. It is pulled out of the housing 21 via (not shown).

  The upper front panel portion 22b has a first operation port 23a for operating an emergency button 31a of a transmitter 30 to be described later and a part of a recovery button 31b of the transmitter 30 to be described later. The sound from the second operation port 23b, the emergency bell 71 of the acoustic device 70 described later, and the sound hole 23c for emitting the sound to the outside of the casing 21, and the light of the indicator lamp 61 of the display device 60 described later. And a light guide hole 23d for guiding light toward the outside. The lower front panel portion 22c is provided with an openable / closable door portion 23e for taking out an AED main body portion 41 of the AED 40 to be described later from the housing 21. Further, the door portion 23e is provided with a door window portion 23f formed of a transparent resin material so that the AED main body portion 41 can be visually recognized from the outside.

(Configuration-Combined notification device-Transmitter)
Next, the configuration of the transmitter 30 will be described. The transmitter 30 is a wired fire alarm terminal that transmits a fire signal, a fire recovery signal, and the like. As shown in FIG. 3, the transmitter 30 includes an operation unit, a communication unit, a confirmation indicator lamp, a control unit, and a storage unit (all not shown). In addition, since this transmitter 30 can be comprised by a well-known wired transmitter etc., the detailed description is abbreviate | omitted.

  The operation unit accepts an operation input to the transmitter 30, and includes an emergency button 31a and a recovery button 31b. Among these, the emergency button 31a is an operation unit that receives a fire signal transmission instruction, and is arranged to be exposed to the outside of the housing 21 through the first operation port 23a. The recovery button 31b is a button for restoring the state of the emergency button 31a to the state before receiving the fire signal transmission instruction by mechanical operation when the fire signal transmission instruction is received through the emergency button 31a. Yes, and disposed so as to be exposed to the outside of the casing 21 through the second operation port 23b.

  The communication unit is a communication unit for performing communication with the receiver 80 via the first wiring 2.

  The confirmation indicator lamp displays that the emergency button 31a has been pressed. The confirmation indicator lamp is configured by using, for example, a known LED lamp, a fluorescent lamp, and the like, and a position in the inside of the casing 21 where the confirmation indicator lamp can be visually recognized from the outside of the casing 21 (for example, the casing) 21 in the vicinity of the first operation port 23a).

  The control unit is a control unit that controls each unit of the transmitter 30. Details of processing executed by the control unit will be described later.

  The storage unit is a storage unit that stores programs and various data necessary for the operation of the transmitter 30. The storage unit is configured by using a rewritable recording medium, and a non-volatile recording medium such as a flash memory can be used (a storage unit 49 of the AED 40 described later and a storage unit 88 of the receiver 80 described later). The same applies to the storage unit of the notification device 90 described later).

(Structure-Combined alarm device-AED)
Next, the configuration of the AED 40 will be described. The AED 40 is a medical device that performs the above-described defibrillation. As shown in FIG. 3, the AED 40 includes an operation unit 42 (at least a part of which is exposed), a detection unit 43, a communication unit 44a, a wireless communication unit 44b, a power supply unit 45, and a display unit 46a. (At least partly exposed), an audio input unit 46b, an audio output unit 46c, an imaging unit 47, a control unit 48, and a storage unit 49. Since the AED 40 can be constituted by, for example, a known AED, detailed description thereof is omitted.

  The AED main body 41 is a basic structure of the AED 40. For example, the main body portion of the known AED 40 (specifically, in order to give an electric shock to a person whose heart cannot be beaten normally). Electrode pads and various sensors (for example, heart rate sensor, blood pressure sensor, etc.) for measuring the health condition of the person. The AED main body 41 is provided with a light guide hole (not shown) for guiding the light from the display unit 46a to the outside.

  The operation unit 42 is an operation unit that receives an operation input to the AED 40, and is configured using a known operation unit such as a switch or a touch panel (the operation unit 81 of the receiver 80 described later and a notification described later). The same applies to the operation unit of the device 90). The operation unit 42 includes a communication stop button 42a. Here, the communication stop button 42a is a communication stop operation means for receiving an instruction to stop communication of a signal including state information described later.

  The detection unit 43 is detection means for detecting the state of the AED 40. Here, “the state of the AED 40” means the state of the AED 40 at a certain point in time, and includes, for example, a use state of the AED 40, a failure state of the AED 40, and a use required state where the use of the AED 40 is required. is there. The detection unit 43 detects a failure state of the AED 40 among the three states of the AED 40 described above. For example, the detection unit 43 detects the presence / absence of an abnormality of the AED 40 (specifically, a power supply abnormality or a function abnormality). For this purpose, a known current sensor is used.

  The communication unit 44 a is a communication unit for performing communication with the receiver 80 via the first wiring 2.

  The wireless communication unit 44b is a second wireless communication unit for performing wireless communication with a wireless communication unit 52 of the relay device 50 described later via a wireless antenna (not shown). This is a second wireless communication means for transmitting the included signal to the display device 60 or the acoustic device 70 via the wireless communication unit 52 of the relay device 50 described later. The wireless communication unit 44b is configured using, for example, a known communication unit that performs communication using a known mobile wireless communication network (the same applies to the wireless communication unit 52 of the relay device 50 described later). And). For the AED 40, in order to enable communication between the AED 40 and the relay device 50, processing for establishing communication between the AED 40 and the relay device 50 (that is, pairing processing) is performed. This is performed before a fire notification process described later and a use state notification process described later are performed.

  The power supply unit 45 is a power supply unit that supplies power supplied from the receiver 80 or the battery to each unit of the AED 40.

  The display unit 46a displays various information based on the control of the control unit 48, and is an image display unit that displays an image. The display unit 46a is configured using, for example, a known LED lamp or a flat panel display such as a known liquid crystal display (the same applies to a display unit 83 of the receiver 80 described later).

  The audio input unit 46b is an audio input unit that inputs audio around the AED 40, converts the input audio into an electrical signal (ie, audio signal), and outputs the electric signal to the control unit 48. A known microphone or the like is used. (The same applies to a voice input unit 84 of the receiver 80 described later).

  The audio output unit 46c is an audio output unit that outputs various kinds of information as audio under the control of the control unit 48, and is configured using, for example, a known speaker.

  The imaging unit 47 is an imaging unit that captures an image around the AED 40, and is configured using a known imaging device such as a CMOS image sensor or a CCD image sensor, and a known optical system component such as a lens or a prism. Yes. The imaging unit 47 converts the captured image into an electrical signal (that is, an image signal), and outputs the converted electrical signal to the control unit 48.

  The control unit 48 is a control unit that controls each unit of the AED 40, and includes a determination unit 48a, an image processing unit 48b, and a call processing unit 48c in terms of functional concept. Here, the determination unit 48 a is a determination unit that determines the state of the AED 40. In addition, the image processing unit 48b is an image processing unit for processing an image captured by the imaging unit 47 of the AED 40 in order to detect the use required state of the AED 40 among the three AED 40 states described above. . In addition, the call processing unit 48c is a call that is performed by voice between the user (user) of the AED 40 and the user of another device different from the AED 40 (such as the administrator of the receiver 80 in the first embodiment). Call processing means for performing processing related to The “detection unit 43”, “determination unit 48a”, and “image processing unit 48b” described above correspond to “determination unit” in the claims. Details of processing executed by the control unit 48 will be described later.

  The storage unit 49 is a storage unit that stores a program and various data necessary for the operation of the AED 40.

(Configuration-Combined notification device-Relay device)
Next, the configuration of the relay device 50 will be described. The relay device 50 is a device that relays a signal wirelessly transmitted from the AED 40 to the display device 60 or the acoustic device 70 via the receiver 80. The relay device 50 includes a communication unit 51, a wireless communication unit 52, and a control unit 53.

  The communication unit 51 is a communication unit for performing communication with the receiver 80 via the second wiring 3.

  The wireless communication unit 52 is a first wireless communication unit that performs wireless communication with the wireless communication unit 44b of the AED 40 via a wireless antenna (not shown).

  The control unit 53 is a control unit that controls each unit of the relay device 50. Details of processing executed by the control unit 53 will be described later.

(Configuration-combined notification device-display device)
Next, the configuration of the display device 60 will be described. The display device 60 is a fire information output device that displays fire information described later. The display device 60 includes an indicator lamp 61, a communication unit 62, and a control unit 63.

  The indicator lamp 61 is an output means and a display means for displaying fire information, which will be described later, and is configured using, for example, a known LED lamp, fluorescent lamp, or the like.

  The communication unit 62 is a communication unit for performing communication with the receiver 80 via the second wiring 3.

  The control unit 63 is a control unit that controls each unit of the display device 60. Details of processing executed by the control unit 63 will be described later.

(Configuration-combined notification device-acoustic device)
Next, the configuration of the acoustic device 70 will be described. The acoustic device 70 is a fire information output device that outputs fire information to be described later with an alarm sound. The acoustic device 70 includes an emergency bell 71, a communication unit 72, and a control unit 73.

  The emergency bell 71 is an output means and an alarm sound output means for outputting fire information to be described later with a bell sound (that is, an alarm sound), and is configured using, for example, a known bell.

  The communication unit 72 is a communication unit for performing communication with the receiver 80 via the third wiring 4.

  The control unit 73 is a control unit that controls each unit of the acoustic device 70. Details of processing executed by the control unit 73 will be described later.

(Configuration-Receiver)
Next, the configuration of the receiver 80 will be described. FIG. 4 is a block diagram showing an electrical configuration of the receiver 80. The receiver 80 performs a predetermined process based on a signal received from the sensor 10, the transmitter 30, the relay device 50, the display device 60, the acoustic device 70, or the notification device 90. As shown in FIG. 4, the receiver 80 includes an operation unit 81, a communication unit 82, a display unit 83, a voice input unit 84, a voice output unit 85, a power supply unit 86, a control unit 87, and a storage unit 88. Configured. The receiver 80 can be configured by, for example, a known receiver, and a detailed description thereof is omitted.

  The operation unit 81 is an operation unit that receives an operation input to the receiver 80.

  The communication unit 82 is connected to the sensor 10, the transmitter 30, the AED 40, the relay device 50, the display device 60, the acoustic device 70, or the notification device 90 for the first wiring 2, the second wiring 3, and the third wiring 4. It is a communication means for performing communication via any one.

  The display unit 83 displays various information based on the control of the control unit 87.

  The audio input unit 84 inputs audio around the receiver 80, converts the input audio into an electric signal, and outputs the electric signal to the control unit 87.

  The audio output unit 85 outputs various types of information as audio based on the control of the control unit 87, and is configured using a known acoustic device such as a speaker or a buzzer.

  The power supply unit 86 supplies power supplied from a commercial power source through any one of the first wiring 2, the second wiring 3, and the third wiring 4 to each unit of the receiver 80, the sensor 10, the transmitter 30, This is power supply means for supplying the AED 40, the relay device 50, the display device 60, the acoustic device 70, and the notification device 90.

  The control unit 87 is a control unit that controls each unit of the receiver 80, and includes a call processing unit 87a in terms of functional concept. Here, the call processing unit 87a is a call processing unit that performs a process related to a call performed by voice between the administrator of the receiver 80 and the user (user) of the AED 40.

  The storage unit 88 is a storage unit that stores a program and various data necessary for the operation of the receiver 80.

(Configuration-reporting device)
Next, the configuration of the notification device 90 will be described. When the notification device 90 receives a signal from the receiver 80, the notification device 90 transmits a predetermined signal (for example, a signal including sound information related to fire information described later or use state information described later) via a telephone line (not shown). This is for reporting to an external device (for example, a center device or a mobile phone). The notification device 90 includes an operation unit, a communication unit, a control unit, and a storage unit (all not shown). In addition, since this notification apparatus 90 can be comprised by a well-known notification apparatus etc., the detailed description is abbreviate | omitted.

  The operation unit is an operation unit that receives an operation input to the notification device 90. The communication unit is a communication unit for performing communication between external devices installed outside the fire alarm system 1. The control unit is a control unit that controls each unit of the notification device 90. The storage unit is a storage unit that stores programs and various data necessary for the operation of the notification device 90.

(processing)
Next, the process performed by the fire alarm system 1 configured as described above will be described. The processes executed by the fire notification system 1 are roughly divided into a fire notification process, a use state notification process, a failure state notification process, and a use necessary state notification process. Hereinafter, each of the fire notification process, the use state notification process, the failure state notification process, and the use necessary state notification process will be described.

(Processing-Fire alarm processing)
First, the fire notification process will be described. FIG. 5 is a flowchart of a fire notification process related to the sensor 10 or the transmitter 30 (steps are abbreviated as “S” in the description of each process below). FIG. 6 is a flowchart of the fire notification process related to the display device 60 or the audio device 70. The fire notification process is a process of performing a fire notification. In the fire notification process, generally, a process of outputting fire information described later to the indicator lamp 61 of the display device 60 or the emergency bell 71 of the acoustic device 70 is performed. The timing for executing this fire alarm processing is arbitrary, but in the first embodiment, after the sensor 10, the transmitter 30, the display device 60, the acoustic device 70, and the receiver 80 are powered on. It is assumed that it is activated. Further, the premise of this fire notification process is as follows (the same applies to the premise of the use state notification process, the premise of the failure state notification process, and the premise of the use necessary state notification process). Specifically, in order to guide the position of the transmitter 30 during normal times, the display lamp 61 of the display device 60 is lit up, and it is assumed that the display lamp 61 is lit up. Further, since the output of the confirmation indicator lamp of the transmitter 30 and the emergency bell 71 of the sound device 70 are stopped at normal times, the output of the confirmation indicator lamp and the emergency bell 71 is stopped.

  When the fire notification process is started, as shown in FIG. 5, in SA1, the control unit of each sensor 10 installed in the building (hereinafter referred to as “each sensor 10”) detects the detection result of the sensor unit. To determine whether a fire has been detected. In addition, the control unit of each transmitter 30 (hereinafter referred to as “each transmitter 30”) installed in the building determines whether or not a fire signal transmission instruction has been received via the emergency button 31a. Here, regarding the determination of the sensor 10, for example, when a fire has occurred in a building, it is determined that a fire has been detected if the temperature (or smoke concentration) detected by the sensor unit exceeds a threshold value. Regarding the determination of the transmitter 30, for example, when a fire occurs in a building, if the emergency button 31a is pressed by a person in the building (for example, a resident or a visitor), the fire signal is transmitted. It is determined that the instruction has been accepted. The control unit of each sensor 10 stands by until it is determined that a fire has been detected, and the control unit of each transmitter 30 until it is determined that a fire signal transmission instruction has been accepted via the emergency button 31a. Waiting (SA1, No), and the controller of each sensor 10 determines that a fire has been detected, or the controller of each transmitter 30 has received a fire signal transmission instruction by operating the emergency button 31a. If determined (SA1, Yes), the process proceeds to SA2.

  In SA2, the control unit of the sensor 10 that has been determined that a fire has been detected in SA1 sends a fire signal to notify the fire to the communication unit and the first wiring 2, the receiver 80, and the second wiring 3 (or the third wiring). The data is transmitted to each display device 60 and each acoustic device 70 (hereinafter referred to as “each display device 60” and “each acoustic device 70”) installed in the building via the wiring 4). In addition, the controller of the transmitter 30 that has been determined in SA1 that the fire signal transmission instruction has been received via the emergency button 31a transmits the fire signal to the communication unit and the first wiring 2, the receiver 80, and the second wiring. 3 (or the third wiring 4) is transmitted to each display device 60 and each acoustic device 70, and in order to notify that the emergency button 31a has been pressed, a confirmation indicator lamp is turned on.

  Next, as shown in FIG. 6, in SB1, the control unit 63 of each display device 60 (or the control unit 73 of each acoustic device 70) detects the sensor 10 (or the determination that a fire has been detected in SA1) (or The fire signal transmitted from the transmitter 30) determined to have received the fire signal transmission instruction via the emergency button 31a in SA1 is the first wiring 2, the receiver 80, the second wiring 3 (or the third wiring). 4) and whether it is received via the communication unit 62 (or the communication unit 72). And the control part 63 (or control part 73 of each acoustic apparatus 70) of each display apparatus 60 waits until a fire signal is received (SB1, No), and when a fire signal is received (SB1, Yes) ), And shifts to SB2.

  In SB2, the control unit 63 of each display device 60 (or the control unit 73 of each acoustic device 70) notifies the fire information to the person in the building by using the indicator lamp 61 (or emergency bell 71). Output. Here, “fire information” is information indicating a fire notification. Although the output of the fire information is arbitrary, in the first embodiment, the indicator lamp 61 lights up in the same manner as the normal display, and the emergency bell 71 continuously emits a bell sound of “jirigiri”. Output to.

  Returning to FIG. 5, in SA3, the control unit of the sensor 10 to which the fire signal is transmitted in SA2 determines whether or not a fire is no longer detected based on the detection result of the sensor unit. Further, the control unit of the transmitter 30 to which the fire signal is transmitted in SA2 determines whether or not the emergency button 31a has been restored to the state before accepting the fire signal transmission instruction. Here, with respect to the determination of the sensor 10, for example, after the fire generated in the building is extinguished, it is determined that the fire is no longer detected when the temperature (or smoke concentration) in the building falls below a threshold value. Further, regarding the determination of the transmitter 30, for example, when the recovery button 31b is pressed by a person in the building or the administrator of the receiver 80 after the fire that has occurred in the building is extinguished, the emergency button 31a It is determined that the state before receiving the transmission instruction is restored. The control unit of the sensor 10 waits until it is determined that the fire is no longer detected, and the control unit of the transmitter 30 is restored to the state before the emergency button 31a accepts the fire signal transmission instruction. Until it is determined that the fire has been detected (SA3, No), or when it is determined that the emergency button 31a has been restored to the state before receiving the fire signal transmission instruction (SA3, Yes) ), Move to SA4.

  In SA4, the control unit of the sensor 10 determined that the fire is no longer detected in SA3 sends a fire recovery signal for notifying that the fire has been extinguished to the communication unit and the first wiring 2, the receiver 80, and the first. It transmits to each display apparatus 60 and each acoustic apparatus 70 via 2 wiring 3 (or 3rd wiring 4). Further, the controller of the transmitter 30 that has been determined that the emergency button 31a has been restored to the state before receiving the fire signal transmission instruction in SA3, the communication unit and the first wiring 2, the receiver 80, And the second wiring 3 (or the third wiring 4) to each display device 60 and each acoustic device 70, and the output state of the confirmation indicator lamp before the transmitter 30 accepts a fire signal transmission instruction. In order to return to the state, the lighting display of the confirmation indicator lamp is stopped after a predetermined time (for example, 60 minutes). Thereafter, the control unit of the sensor 10 (or the control unit of the transmitter 30) shifts to SA1, and thereafter similarly performs the processing from SA1 to SA4.

  Next, as shown in FIG. 6, in SB3, the control unit 63 of each display device 60 (or the control unit 73 of each acoustic device 70) determines that the sensor 10 (or the determination that a fire is no longer detected in SA3) (or The fire restoration signal transmitted from the transmitter 30) determined that the emergency button 31a has been restored in SA3 is used as the first wiring 2, the receiver 80, the second wiring 3 (or the third wiring 4), and the communication unit 62. It is determined whether or not it has been received via (or communication unit 72). And the control part 63 (or control part 73 of each acoustic apparatus 70) of each display apparatus 60 waits until a fire recovery signal is received (SB3, No), and when a fire recovery signal is received (SB3) , Yes), the process proceeds to SB4.

  In SB4, the control unit 63 of each display device 60 (or the control unit 73 of each acoustic device 70) stops the output of fire information by the indicator lamp 61 (or emergency bell 71). Here, the stop of the output of the fire information is arbitrary, but in the first embodiment, the emergency bell 71 stops outputting while the indicator lamp 61 performs the normal display (that is, lighting display). Further, when each display device 60 and each acoustic device 70 receives a fire signal from a plurality of detectors 10 and transmitters 30, a fire recovery signal is transmitted from only a part of the plurality of sensors 10 and transmitters 30. When received, the fire information is continuously output by the indicator lamp 61 of each display device 60 and the emergency bell 71 of each acoustic device 70, and fire recovery signals are received from all of the plurality of sensors 10 and the transmitter 30. In this case, the output of fire information by the indicator lamp 61 of each display device 60 and the emergency bell 71 of each acoustic device 70 is stopped. Thereafter, the control unit 63 of each display device 60 (or the control unit 73 of each acoustic device 70) shifts to SB1, and thereafter similarly performs the processing from SB1 to SB4.

(Processing-usage status notification process)
Next, the usage state notification process will be described. FIG. 7 is a flowchart of the use state notification process regarding the AED 40. FIG. 8 is a flowchart of a use state notification process regarding the display device 60 or the acoustic device 70. The usage state notification process is a process for notifying the usage state of the AED 40. In the use state notification process, generally, a process of outputting use state information to be described later to the indicator lamp 61 of the display device 60 or the emergency bell 71 of the acoustic device 70 is performed. In addition, in the first embodiment, a part of the AED 40 (specifically, the wireless communication unit 44b, the control unit 48, etc.), the relay device 50, and the display are performed. The description will be made assuming that the apparatus 60, the sound apparatus 70, and the receiver 80 are activated after being turned on and are executed in parallel with the above-described fire notification process.

  When the usage state notification process is started, as shown in FIGS. 7 and 8, among the people in the building, the usage state information described later is displayed on the display device 60 to a third party other than the user of the AED 40. Each AED 40 installed in the building (hereinafter referred to as “each AED 40”) can be presented by the indicator lamp 61 or the emergency bell 71 of the sound device 70 and can prevent erroneous reporting of usage state information to be described later. The control unit 48 performs SC1 to SC3, and the control unit 63 of each display device 60 (or the control unit 73 of each acoustic device 70) performs processing of SD1 and SD2.

  First, as shown in FIG. 7, in SC1, the determination unit 48a of each AED 40 determines whether or not the AED 40 is in use. The determination as to whether or not the AED 40 is in use is optional, but in the first embodiment, an activation instruction for activating the AED 40 (particularly the AED main body 41) is received via the operation unit 42. It is determined based on whether or not Here, the determination unit 48a of each AED 40 determines that the AED 40 is in use when the activation instruction is accepted, and determines that the AED 40 is not in use when the activation instruction is not accepted. To do. When the determination unit 48a of each AED 40 determines that the AED 40 is not in use (SC1, No), the process of SC1 is repeated until the AED 40 is determined to be in use, until the AED 40 is used. When it is determined that the state is in the state (SC1, Yes), the process proceeds to SC2.

  In SC2, the controller 48 of the AED 40 determined to be in use in SC1 determines whether or not a communication stop instruction for a use state signal, which will be described later, has been received via the communication stop button 42a. For example, it is determined whether or not the communication stop button 42a has been operated immediately before the processing of SC1 or within a predetermined time (for example, within 10 seconds) after the AED 40 is determined to be in use in SC1. When the communication stop button 42a is operated immediately before the processing of SC1 or within a predetermined time, it is determined that a communication stop instruction of a use state signal described later has been received, and the communication stop button immediately before the processing of SC1 or within the predetermined time When 42a is not operated, it determines with the communication stop instruction | indication of the use status signal mentioned later not having been received. Then, when it is determined that a communication stop instruction for a use state signal, which will be described later, has not been received (No in SC2), the control unit 48 of the AED 40 proceeds to SC3. On the other hand, when it is determined that a communication stop instruction for a use state signal to be described later has been received (SC2, Yes), output of use state information to be described later by the indicator lamp 61 of the display device 60 or the emergency bell 71 of the audio device 70 is avoided. Therefore, by shifting to SC1, communication of a use state signal described later by the indicator lamp 61 or the emergency bell 71 is stopped. With such a process, for example, when an administrator of the receiver 80 checks the AED 40, usage state information described later is output by the indicator lamp 61 of the display device 60 (or the emergency bell 71 of the acoustic device 70). Therefore, although the AED 40 is not used, it is possible to prevent erroneous use status information described later. Here, “inspection” means inspecting whether the AED 40 is abnormal.

  In SC3, the control unit 48 of the AED 40 determined to be in use in SC1 generates a use state signal, and the generated use state signal is received by the wireless communication unit 44b, the relay device 50, the first wiring 2, and the reception. It transmits to each display device 60 and each acoustic device 70 via the machine 80 and the second wiring 3 (or the third wiring 4). Here, the “use state signal” is a signal including state information indicating that the AED 40 is in use (hereinafter referred to as “use state information”), and is generated in a predetermined format. Regarding the transmission of the usage state signal, specifically, first, the control unit 48 of the AED 40 transmits the usage state signal to the relay device 50 via the wireless communication unit 44b. Next, the control unit 53 of the relay device 50 receives the usage state signal transmitted from the AED 40 via the wireless communication unit 52, and receives the received usage state signal via the communication unit 51 and the first wiring 2. To the machine 80. Next, the control unit 87 of the receiver 80 receives the usage state signal transmitted from the relay device 50 via the communication unit 82, and the received usage state signal is transmitted to the communication unit 82 and the second wiring 3 (or the third wiring 3). It transmits to each display device 60 and each acoustic device 70 via the wiring 4) (the same applies to the transmission of the non-use state signal of SC5 described later).

  It should be noted that immediately before or immediately after the processing of SC3, the user of the AED 40 is connected to the receiver 80 by the dialogue between the user of the AED 40 determined to be in use in SC1 and the manager of the receiver 80, etc. The following processing may be performed so that advice on the use of the AED 40 can be received from an administrator or the like. For example, when a predetermined operation is accepted via the operation unit 42 of the AED 40, the call processing unit 48c of the AED 40 performs a voice operation between the user of the AED 40 and the manager of the receiver 80 or the like. Process related to incoming calls. Specifically, the call processing unit 48c of the AED 40 transmits a voice signal including voice input via the voice input unit 46b or an image signal including an image captured by the imaging unit 47 to the wireless communication unit 44b and the relay. The data is transmitted to the receiver 80 via the device 50 and the first wiring 2. In this case, the call processing unit 87a of the receiver 80 causes the audio output unit 46c to output the audio included in the audio signal received from the AED 40 via the relay device 50, the first wiring 2, and the communication unit 82. The image included in the image signal received from the AED 40 via the relay device 50, the first wiring 2, and the communication unit 82 is displayed on the display unit 83. The call processing unit 48c of the AED 40 is a voice signal transmitted from the receiver 80, and includes a voice signal including voice input via the voice input unit 84 of the receiver 80, a method for using the AED 40, lifesaving When an image signal including an image related to a method or the like is received via the first wiring 2, the relay device 50, and the wireless communication unit 44b, the audio output unit 46c outputs the audio included in the received audio signal. The image included in the received image signal is displayed on the display unit 46a. Through such processing, the user of the AED 40 can receive advice on the use of the AED 40 from the manager of the receiver 80 and the like through a dialogue between the user of the AED 40 and the manager of the receiver 80. In addition, images can be exchanged between the user of the AED 40 and the manager of the receiver 80. Therefore, for example, an administrator of the receiver 80 or the like can accurately grasp the surroundings of the AED 40 based on the image received from the AED 40. Further, it becomes possible for the user of the AED 40 to accurately grasp advice on the use of the AED 40 based on the image received from the receiver 80.

  Next, as shown in FIG. 8, in SD1, the control unit 63 of each display device 60 (or the control unit 73 of each acoustic device 70) is transmitted from the AED 40 determined to be in use in SC1. It is determined whether the status signal is received via the relay device 50, the first wiring 2, the receiver 80, the second wiring 3 (or the third wiring 4), and the communication unit 62 (or the communication unit 72). Then, the control unit 63 of each display device 60 (or the control unit 73 of each acoustic device 70) waits until the usage state signal is received (SD1, No), and when the usage state signal is received (SD1). , Yes), the process proceeds to SD2.

  In SD2, the control unit 63 of each display device 60 (or the control unit 73 of each acoustic device 70) displays the use state information included in the use state signal received in SD1 by the indicator lamp 61 (or emergency bell 71). Output. The output of the use state information is arbitrary. For example, the indicator lamp 61 displays a time interval or display color different from the display of the fire information so that the use state information can be output distinguishably from the fire information. Or, the emergency bell 71 outputs the usage state information in a mode different from the fire information by outputting it at a different time interval or tone color from the output of the fire information. In the first embodiment, when the display of the fire information by the indicator lamp 61 is a lit display, the display of the use state information by the indicator lamp 61 is blinked at a predetermined time interval (for example, 3 sec interval). . In addition, when the fire bell 71 outputs the bell sound “Jirijiri” continuously, the emergency bell 71 uses the bell sound “Jirijiri” for a predetermined time interval (for example, For example, every 3 seconds).

  Through the above processing, even when the AED 40 is used at a location away from the wireless communication unit 52, the signal including the state information transmitted from the AED 40 is transmitted via the wireless communication unit 52 to the display device 60 or the acoustic device 70. Can be received and state information can be presented to the person in the building. Thereby, the person in the building can grasp the state of the AED 40 and can quickly take necessary measures according to the state of the AED 40 as compared with the conventional technique. In particular, in the usage status notification process, usage status information can be presented to a person in a building. As a result, since the person in the building can grasp that the AED 40 is in use, the AED 40 is used to perform lifesaving activities for a person whose heart cannot be beaten normally. In this case, the user of the AED 40 can easily receive support for lifesaving activities from a third party other than the user. Further, since the fire information and the state information are output by the indicator lamp 61 of the display device 60 or the emergency bell 71 of the sound device 70, for example, an output unit that outputs only the fire information, and an output unit that outputs only the state information Compared with the case where each is provided, the installation space can be reduced, and the installation space can be made compact. In addition, the state information can be displayed and presented on the indicator lamp 61 of the display device 60 to the person in the building, and the use state information can be easily and reliably transmitted to the person in the building. Moreover, state information can be output to the emergency bell 71 of the audio device 70 and presented to the person in the building through hearing. Therefore, when the person in the building is in a position where the display lamp 61 of the display device 60 cannot be viewed, or the display lamp 61 of the display device 60 can be viewed, it is displayed on the display lamp 61. Even when it is difficult to visually recognize the information, it is possible to quickly convey the state information.

  Note that, as described above, since this use state notification process is executed in parallel with the fire notification process, for example, when the fire notification process SB2 is executed, the use state signal is received at SD1. If so, SD2 is executed. That is, it is assumed that the output of fire information and the output of usage state information overlap. In such a case, for example, the control unit 63 of each display device 60 uses the indicator light 61 so that both the fire information and the usage state information can be presented to the person in the building. The information is alternately displayed at predetermined time intervals (for example, every 20 seconds), and the control unit 73 of each acoustic device 70 alternately outputs fire information and use state information at predetermined time intervals by the emergency bell 71. (Also, the same applies to the output of failure state information in a failure state notification process described later and the use state information in a use necessary state notification process described later). Alternatively, from the viewpoint of the reliability and reliability of fire notification, in order to prioritize the output of fire information, the control unit 63 of each display device 60 until the fire recovery signal is received at SB3 of the fire notification process, Only the fire information may be displayed by the indicator lamp 61, and the control unit 73 of each acoustic device 70 may output only the fire information by the emergency bell 71 (note that failure state information of a failure state notification process to be described later) The same applies to the output of the use state information of the use necessary state notification process described later).

  Next, as shown in FIGS. 7 and 8, in order to return the output state of each display device 60 or each acoustic device 70 to the state before the AED 40 is used, a use state signal is transmitted in SC3. The control unit 48 of the AED 40 performs processing of SC4 and SC5, and the control unit 63 of each display device 60 (or the control unit 73 of each acoustic device 70) performs processing of SD3 and SD4.

  First, as shown in FIG. 7, in SC4, the determination unit 48a of the AED 40 to which the use state signal is transmitted in SC3 determines whether or not the AED 40 is in a non-use state. Here, the determination as to whether or not the AED 40 is in a non-use state is arbitrary, but in the first embodiment, a predetermined time (for example, for example, after the AED 40 is determined to be in a use state in SC1). If the AED 40 is determined to be in use by the SC 1 or not, a stop instruction for stopping the driving of the AED 40 (in particular, the AED main body 41) is issued to the operation unit 42. It is determined based on whether or not it is accepted via The reason for performing the determination in consideration of the passage of the predetermined time as described above is that when it is determined whether or not the AED 40 is in a non-use state based only on whether or not a stop instruction is accepted, the AED 40 Even if the AED 40 is driven again after the driving of the AED is stopped, it is determined that the AED 40 is not in use, so that this situation is avoided. Specifically, the determination unit 48a of the AED 40 exceeds a predetermined time after it is determined in SC1 that the AED 40 is in use, and after it is determined in SC1 that the AED 40 is in use. When the stop instruction is accepted, it is determined that the AED 40 is not in use. On the other hand, a predetermined time has not elapsed since the AED 40 was determined to be in use in SC1, or a stop instruction has not been received since the AED 40 was determined to be in use in SC1. In this case, it is determined that the AED 40 is not in an unused state. When the AED 40 is determined not to be in an unused state (No in SC4), the determination unit 48a of the AED 40 repeats the process in SC4 until it is determined that the AED 40 is in an unused state. When it determines with it being a non-use state (SC4, Yes), it transfers to SC5.

  In SC5, the control unit 48 of the AED 40 determined to be in the non-use state in SC4 generates a non-use state signal, and the generated non-use state signal is transmitted to the wireless communication unit 44b, the relay device 50, and the first wiring. 2. Transmit to each display device 60 and each acoustic device 70 via the receiver 80 and the second wiring 3 (or the third wiring 4). Here, the “non-use state signal” is a signal including non-use state information indicating that the AED 40 is in a non-use state, and is generated in a predetermined format. Thereafter, the control unit 48 of the AED 40 shifts to SC1, and thereafter similarly performs the processing from SC1 to SC5.

  Next, as shown in FIG. 8, in SD3, the control unit 63 of each display device 60 (or the control unit 73 of each acoustic device 70) is transmitted from the AED 40 that is determined to be unused in SC4. It is determined whether or not the unused state signal is received via the relay device 50, the first wiring 2, the receiver 80, the second wiring 3 (or the third wiring 4), and the communication unit 62 (or the communication unit 72). To do. And the control part 63 (or control part 73 of each acoustic apparatus 70) of each display apparatus 60 waits until a non-use state signal is received (SD3, No), and when a non-use state signal is received. (SD3, Yes), the process proceeds to SD4.

  In SD4, the control unit 63 of each display device 60 (or the control unit 73 of each acoustic device 70) stops the output of the usage state information by the indicator lamp 61 (or emergency bell 71). Here, the stop of the output of the use state information is arbitrary, but in the first embodiment, the emergency bell 71 stops outputting while the indicator lamp 61 performs the normal display (that is, the lighting display) ( The same applies to the stop of output of failure state information in a failure state notification process described later and the stop of output of use necessary state information in a use necessary state notification process described later). Further, when each display device 60 and each acoustic device 70 receives a use state signal from a plurality of AEDs 40, each display device 60 receives a non-use state signal from only a part of the plurality of AEDs 40. When the output of the use state information by the emergency bell 71 of each of the display devices 61 and the sound devices 70 is continued and the non-use state signals are received from all of the plurality of AEDs 40, the display light 61 of each display device 60 and The output of the usage state information by the emergency bell 71 of each acoustic device 70 is stopped. Thereafter, the control unit 63 of each display device 60 (or the control unit 73 of each acoustic device 70) shifts to SD1, and thereafter similarly performs the processing from SD1 to SD4.

(Processing-Failure status notification process)
Next, the failure state notification process will be described. FIG. 9 is a flowchart of the failure state notification process regarding the AED 40. FIG. 10 is a flowchart of the failure state notification process regarding the display device 60 or the acoustic device 70. The failure state notification process is a process for notifying that the AED 40 is in a failure state. In addition, in the first embodiment, a part of the AED 40 (specifically, the detection unit 43, the wireless communication unit 44b, and the control unit 48), the relay device, is performed although the timing for executing the failure state notification process is arbitrary. 50, the display device 60, and the sound device 70 are started after power is turned on, and are described as being executed in parallel with the above-described fire notification process and use state notification process.

  When the failure state notification process is activated, as shown in FIGS. 9 and 10, failure state information to be described later is sent to the person in the building by the indicator lamp 61 of the display device 60 or the emergency bell 71 of the acoustic device 70. As can be shown, the control unit 48 of each AED 40 performs SE1 and SE2, and the control unit 63 of each display device 60 (or the control unit 73 of each acoustic device 70) performs the processing of SF1 and SF2. Do.

  First, as shown in FIG. 9, in SE1, the determination unit 48a of each AED 40 determines whether or not the AED 40 is in a failure state. The determination as to whether or not the AED 40 is in a failure state is arbitrary, but in the first embodiment, the detection result of the detection unit 43 (for example, the current value detected by the detection unit 43 and the AED 40 Is determined based on whether or not an abnormality (for example, a power supply abnormality or a functional abnormality) has occurred in the AED 40. Here, the determination unit 48a of each AED 40 determines that the AED 40 is in a failure state when an abnormality has occurred in the AED 40 because a part of the detection result by the detection unit 43 does not satisfy the reference value. To do. On the other hand, when all the detection results by the detection unit 43 satisfy the reference value, it is determined that the AED 40 is not in a failure state when no abnormality has occurred in the AED 40. Then, when it is determined that the AED 40 is not in a failure state (SE1, No), the determination unit 48a of each AED 40 repeats the process of SE1 until it is determined that the AED 40 is in a failure state, and the AED 40 fails. When it is determined that the state is in the state (SE1, Yes), the process proceeds to SE2.

  In SE2, the control unit 48 of the AED 40 determined to be in the failure state in SE1 generates a failure state signal, and the generated failure state signal is transmitted to the wireless communication unit 44b, the relay device 50, and the fourth wiring 5. Then, the data is transmitted to the display device 60 and the acoustic device 70 accommodated in the casing 21 in which the AED 40 is accommodated. Here, the “failure state signal” is a signal including state information (hereinafter referred to as “failure state information”) indicating that the AED 40 is in a failure state, and is generated in a predetermined format. Regarding the transmission of the failure state signal, specifically, first, the control unit 48 of the AED 40 transmits the failure state signal to the relay device 50 via the wireless communication unit 44b. Next, the control unit 53 of the relay device 50 receives the failure state signal from the AED 40 via the wireless communication unit 52, and the AED 40 is accommodated via the communication unit 51 and the fourth wiring 5. Transmitted to the display device 60 and the acoustic device 70 accommodated in the housing 21 (note that a failure state recovery signal described later is transmitted, a use necessary state signal described later is transmitted, and a use unnecessary state signal described later is transmitted). The same shall apply).

  Next, as shown in FIG. 10, in SF1, the control unit 63 of each display device 60 (or the control unit 73 of each acoustic device 70) is a failure transmitted from the AED 40 determined to be in a failure state in SE1. It is determined whether the status signal is received via the relay device 50, the fourth wiring 5, and the communication unit 62 (or the communication unit 72). Then, the control unit 63 of each display device 60 (or the control unit 73 of each acoustic device 70) waits until the failure state signal is received (SF1, No), and when the failure state signal is received. (SF1, Yes), the process proceeds to SF2.

  In SF2, the control unit 63 of the display device 60 (or the control unit 73 of the acoustic device 70) that has received the failure state signal in SF1 is included in the failure state signal by the indicator lamp 61 (or emergency bell 71). Output fault status information. Although the output of the failure state information is arbitrary, in the first embodiment, the display of the fire information by the indicator lamp 61 is a lighting display, and the display of the usage state information by the indicator lamp 61 is a blinking display at intervals of 3 sec. In some cases, the display of the failure state information by the indicator lamp 61 blinks at intervals of 10 seconds. Also, when the emergency bell 71 outputs the fire information “girijiri” continuously, the use status information output by the emergency bell 71 “girijiri” outputs the bell sound intermittently at intervals of 3 sec. In addition, as the output of the failure state information by the emergency bell 71, the bell sound “jirigiri” is intermittently output at intervals of 10 sec.

  Through the processing as described above, failure state information can be presented to the person in the building. Accordingly, a person in the building can grasp that the AED 40 is in a failure state, and can quickly inspect and repair the AED 40.

  Next, as shown in FIGS. 9 and 10, in order to return the output state of the display device 60 or the acoustic device 70 from which the failure state information was output in SF2 to the state before the abnormality occurred in the AED 40, in SE2. The control unit 48 of the AED 40 to which the failure state signal is transmitted performs the processing of SE3 and SE4, and the display device 60 or the acoustic device 70 to which the failure state information is output in SF2 performs the processing of SF3 and SF4.

  First, as shown in FIG. 9, in SE3, the determination unit 48a of the AED 40 to which the failure state signal is transmitted in SE2 makes a determination based on whether or not the AED 40 has recovered from the failure state to the normal state. Although determination as to whether or not the AED 40 has been restored is arbitrary, in the first embodiment, determination is made based on whether or not an abnormality has occurred in the AED 40 based on the detection result of the detection unit 43. Here, the determination unit 48a of the AED 40 determines that the AED 40 has not been restored when an abnormality has occurred in the AED 40 because a part of the detection result of the detection unit 43 does not satisfy the reference value. To do. On the other hand, when all the detection results by the detection unit 43 satisfy the reference value, it is determined that the AED 40 has been restored when no abnormality has occurred in the AED 40. Then, when it is determined that the AED 40 has not been restored (No in SE3), the determination unit 48a of the AED 40 repeats the process of SE3 until it is determined that the AED 40 has been restored, and the AED 40 has been restored. (SE3, Yes), the process proceeds to SE4.

  In SE4, the control unit 48 of the AED 40 determined that the AED 40 has been recovered in SE3 generates a failure recovery signal, and the generated failure recovery signal is transmitted to the wireless communication unit 44b, the relay device 50, and the fourth wiring 5. Then, the data is transmitted to the display device 60 and the acoustic device 70 accommodated in the casing 21 in which the AED 40 is accommodated. Here, the “failure state recovery signal” is a signal including failure state recovery information indicating that the AED 40 has recovered from the failure state to the normal state, and is generated in a predetermined format. Thereafter, the control unit 48 of the AED 40 shifts to SE1, and thereafter similarly performs the processing from SE1 to SE4.

  Next, as shown in FIG. 10, in SF1, the control unit 63 of each display device 60 (or the control unit 73 of each acoustic device 70) transmits a failure transmitted from the AED 40 determined to have recovered the AED 40 in SE3. It is determined whether or not the state restoration signal is received via the relay device 50, the fourth wiring 5, and the communication unit 62 (or the communication unit 72). Then, the control unit 63 of the display device 60 (or the control unit 73 of the acoustic device 70) waits until the failure state recovery signal is received (SF3, No), and the failure state recovery signal is received. If (SF3, Yes), the process proceeds to SF4.

  In SF4, the control unit 63 of the display device 60 (or the control unit 73 of the acoustic device 70) that has received the failure state recovery signal in SF3 outputs the failure state information by the indicator lamp 61 (or emergency bell 71). Stop. Thereafter, the control unit 63 of the display device 60 (or the control unit 73 of the acoustic device 70) shifts to SF1, and thereafter similarly performs the processing from SF1 to SF4.

(Processing-use required state notification process)
Next, the use necessary state notification process will be described. FIG. 11 is a flowchart of the use necessity state notification process regarding the AED 40. FIG. 12 is a flowchart of a use necessity state notification process related to the display device 60 or the audio device 70. The use required state notification process is a process for notifying that the AED 40 is in a use required state. In addition, in the first embodiment, a part of the AED 40 (specifically, the wireless communication unit 44b, the imaging unit 47, and the control unit 48), the relay is performed, although the timing for executing the use necessary state notification process is arbitrary. Description will be made assuming that the apparatus 50, the display apparatus 60, and the acoustic apparatus 70 are activated after being turned on and are executed in parallel with the above-described fire notification process, use state notification process, and failure state notification process.

  When the use necessary state notification process is activated, as shown in FIGS. 11 and 12, the use necessary state information described later is displayed on the display lamp 61 of the display device 60 or the emergency bell of the acoustic device 70 for a person in the building. 71, the control unit 48 of each AED 40 performs SG1 to SG4, and the control unit 63 of each display device 60 (or the control unit 73 of each acoustic device 70) of SH1 and SH2 Process.

  First, as shown in FIG. 11, in SG1, the control unit 48 of each AED 40 determines whether or not an image captured by the imaging unit 47 at a predetermined timing (for example, every 30 min) is acquired from the imaging unit 47. judge. And the control part 48 of each AED40 waits until the said image is acquired (SG1, No), and when the said image is acquired (SG1, Yes), it transfers to SG2.

  In SG2, the image processing unit 48b of the AED 40 from which an image has been acquired in SG1 processes the image using a known image processing method. The image processing of this image is arbitrary. For example, a shape having a predetermined contour is extracted from this image, and the extracted shape and data for specifying the posture of a person stored in advance in the storage unit 49 are used. By performing matching, the posture of a person included in this image is specified (the same applies to image processing of an image in SG6 described later).

  In SG3, the determination unit 48a of the AED 40 whose image is acquired in SG1 determines whether or not the AED 40 is in a use-needed state. The determination as to whether or not the AED 40 is in a use-necessary state is arbitrary, but in the first embodiment, the image processed in SG2 has a shape having the contour of a person who has fallen on the ground. Determine based on whether or not. Here, the determination unit 48a of the AED 40 determines that the AED 40 is in a use-necessary state when the image processed in SG2 includes a shape having a contour of a person who has fallen on the ground. On the other hand, if the image processed in SG2 does not have a shape having the contour of a person who is lying on the ground, it is determined that the AED 40 is not in a use-needed state. And when the determination part 48a of this AED40 determines with this AED40 not being in a use required state (SG3, No), it transfers to SG1, and until it determines with this AED40 being in a use required state in SG3, The process from SG1 to SG3 is repeated. On the other hand, when it is determined that the AED 40 is in a use-needed state (SG3, Yes), the process proceeds to SG4.

  In SG4, the control unit 48 of the AED 40 determined to be in the use required state in SG3 generates a use required state signal, and the generated use required state signal is transmitted to the wireless communication unit 44b, the relay device 50, and the fourth. The data is transmitted to the display device 60 and the acoustic device 70 accommodated in the casing 21 in which the AED 40 is accommodated via the wiring 5. Here, the “use required state signal” is a signal including state information indicating that the AED 40 is in a use required state (hereinafter referred to as “use required state information”), and is generated in a predetermined format.

  Next, as shown in FIG. 12, in SH1, the control unit 63 of each display device 60 (or the control unit 73 of each acoustic device 70) is transmitted from the AED 40 determined to be in a use-needed state in SG3. It is determined whether the use necessary state signal is received via the relay device 50, the fourth wiring 5, and the communication unit 62 (or the communication unit 72). Then, the control unit 63 of each display device 60 (or the control unit 73 of each acoustic device 70) waits until the use necessary state signal is received (SH1, No), and the use necessary state signal is received. If (SH1, Yes), the process proceeds to SH2.

  In SH2, the control unit 63 of the display device 60 (or the control unit 73 of the sound device 70) that has received the use necessity state signal in SH1 uses the indicator lamp 61 (or emergency bell 71) to convert the use necessity state signal. Outputs the necessary use state information included. Although the output of the failure state information is arbitrary, in the first embodiment, the display of the fire information by the indicator lamp 61 is a lighting display, and the display of the usage state information by the indicator lamp 61 blinks at intervals of 3 sec. When the display of the failure state information by the indicator lamp 61 is blinking at intervals of 10 sec, the display is flashed at intervals of 6 sec as the display of necessary use state information by the indicator lamp 61. Moreover, the output of the fire information by the emergency bell 71 continuously outputs a bell sound of “jirigiri”, and the output of the use state information by the emergency bell 71 outputs a bell sound of “jirigiri” intermittently at intervals of 3 sec. When the output of the failure state information by the emergency bell 71 is intermittently output at 10 sec intervals, the bell sound “jirigiri” is output at the intervals of 6 seconds as the output of the use necessary state information by the emergency bell 71. Output intermittently.

  Through the processing as described above, use necessary state information can be presented to the person in the building. Thereby, the person in a building can grasp that the AED 40 is in a use-needed state, and can use the AED 40 quickly.

  Next, as shown in FIG. 11 and FIG. 12, the person who has fallen to the ground in the image processed in SG2 shows the output state of the display device 60 or the acoustic device 70 in which the use necessary state information is output in SH2. The control unit 48 of the AED 40 to which the use necessary state signal is transmitted in SG4 performs processing from SG5 to SG8, and the use necessary state information is displayed in SH2 in order to return to the state before the shape having the contour of The output display device 60 or acoustic device 70 that has been output performs the processing of SH3 and SH4.

  First, as illustrated in FIG. 11, in SG5, the control unit 48 of the AED 40 to which the use necessary state signal is transmitted in SG4 acquires an image captured by the imaging unit 47 at a predetermined timing from the imaging unit 47. Determine whether or not. And the control part 48 of this AED40 waits until the said image is acquired (SG5, No), and when the said image is acquired (SG5, Yes), it transfers to SG6.

  In SG6, the image processing unit 48b of the AED 40 from which an image is acquired in SG5 processes the image using a known image processing method.

  In SG7, the determination unit 48a of the AED 40 whose image has been acquired in SG5 determines whether or not the AED 40 is in a use unnecessary state. The determination as to whether or not the AED 40 is in a use-unnecessary state is arbitrary, but in the first embodiment, the image processed in SG6 has a shape having the contour of a person who is lying on the ground. Determine based on whether or not. Here, the determination unit 48a of the AED 40 determines that the AED 40 is not in a use-unnecessary state when the image processed in SG6 includes a shape having a contour of a person who is lying on the ground. On the other hand, if the image processed in SG6 does not have a shape having the contour of a person who is lying on the ground, it is determined that the AED 40 is in an unnecessary state. And when the determination part 48a of this AED40 determines with this AED40 not being a use unnecessary state (SG7, No), it transfers to SG5, and until it determines with this AED40 being a use unnecessary state in SG7, The process from SG5 to SG7 is repeated. On the other hand, when it is determined that the AED 40 is in an unnecessary state (SG7, Yes), the process proceeds to SG8.

  In SG8, the control unit 48 of the AED 40 determined to be in the use unnecessary state in SG7 generates a use unnecessary state signal, and the generated use unnecessary state signal is transmitted to the wireless communication unit 44b, the relay device 50, and the fourth. The data is transmitted to the display device 60 and the acoustic device 70 accommodated in the casing 21 in which the AED 40 is accommodated via the wiring 5. Here, the “useless state signal” is a signal including useless state information indicating that the AED 40 is in a useless state, and is generated in a predetermined format. Thereafter, the control unit 48 of the AED 40 shifts to SG1, and thereafter similarly performs the processing from SG1 to SG8.

  Next, as shown in FIG. 12, in SH3, the control unit 63 of the display device 60 (or the control unit 73 of the acoustic device 70) to which the use necessary state information is output in SH2 is in the use unnecessary state in SG7. It is determined whether an unnecessary state signal transmitted from the AED 40 determined to be present has been received via the relay device 50, the fourth wiring 5, and the communication unit 62 (or the communication unit 72). Then, the control unit 63 of the display device 60 (or the control unit 73 of the acoustic device 70) waits until the use unnecessary state signal is received (SH3, No), and the use unnecessary state signal is received. If (SH3, Yes), the process proceeds to SH4.

  In SH4, the control unit 63 of the display device 60 (or the control unit 73 of the acoustic device 70) that has received the use necessity state signal in SH1 outputs the use necessary state information by the indicator lamp 61 (or emergency bell 71). Stop. Thereafter, the control unit 63 of the display device 60 (or the control unit 73 of the acoustic device 70) shifts to SH1, and thereafter performs the processing from SH1 to SH4 in the same manner.

(effect)
As described above, according to the first embodiment, the AED 40 wirelessly communicates a signal including the state information indicating the state of the AED 40 to the wireless communication unit 52 based on the determination result of the determination unit 48a and the like. 44b, and when the display device 60 or the acoustic device 70 receives a signal including the state information transmitted from the wireless communication unit 44b via the wireless communication unit 52, the state information is displayed on the indicator lamp 61 or the emergency bell. 71, even when the AED 40 is used in a place away from the wireless communication unit 52, the display device 60 or the acoustic device 70 transmits the signal including the state information transmitted from the AED 40 via the wireless communication unit 52. It is possible to receive the information and to present the state information to the person in the building. Thereby, the person in the building can grasp the state of the AED 40 and can quickly take necessary measures according to the state of the AED 40 as compared with the conventional technique. Further, since the fire information and the state information are output by the indicator lamp 61 of the display device 60 or the emergency bell 71 of the sound device 70, for example, an output unit that outputs only the fire information, and an output unit that outputs only the state information Compared with the case where each is provided, the installation space can be reduced, and the installation space can be made compact.

  When the wireless communication unit 44b determines that the AED 40 is in use by the determination unit 48a, the AED 40 wirelessly communicates the use state signal to the wireless communication unit 52. Usage status information. As a result, since the person in the building can grasp that the AED 40 is in use, the AED 40 is used to perform lifesaving activities for a person whose heart cannot be beaten normally. In this case, the user of the AED 40 can easily receive support for lifesaving activities from a third party other than the user.

  In addition, when the wireless communication unit 44b determines that the AED 40 is in a failure state by the detection unit 43 and the determination unit 48a, the wireless communication unit 44b wirelessly communicates the failure state signal to the wireless communication unit 52. On the other hand, the AED 40 can present failure state information. Accordingly, a person in the building can grasp that the AED 40 is in a failure state, and can quickly inspect and repair the AED 40.

  In addition, when the wireless communication unit 44b determines that the AED 40 is in a use-necessary state by the determination unit 48a and the image processing unit 48b, the use-necessary state signal is wirelessly communicated to the wireless communication unit 52. The AED 40 can present necessary use state information to a person who is present. Thereby, the person in a building can grasp that the AED 40 is in a use-needed state, and can use the AED 40 quickly.

  In addition, when the display device 60 receives a signal including state information transmitted from the wireless communication unit 44b via the wireless communication unit 52, the display device 60 displays the state information on the indicator lamp 61. Thus, the state information can be displayed and displayed on the indicator lamp 61, and the state information can be easily and reliably transmitted to the person in the building.

  In addition, when the acoustic device 70 receives a signal including state information transmitted from the wireless communication unit 44b via the wireless communication unit 52, the sound device 70 outputs the state information to the emergency bell 71. Can present state information through hearing. Therefore, when the person in the building is in a position where the display lamp 61 of the display device 60 cannot be viewed, or the display lamp 61 of the display device 60 can be viewed, it is displayed on the display lamp 61. Even when it is difficult to visually recognize the information, it is possible to quickly convey the state information.

  In addition, when the wireless communication unit 44b receives an instruction to stop communication of a signal including state information via the communication stop button 42a, the communication of the signal including the state information is stopped. When an administrator or the like inspects the AED 40, it is possible to prevent the status information from being output by the indicator lamp 61 of the display device 60 (or the emergency bell 71 of the acoustic device 70), so that the AED 40 is not used. Regardless, state information can be prevented from being erroneously output.

  Further, the AED 40 performs processing related to a voice call between the voice input unit 46b for inputting voice, the voice output unit 46c for outputting voice, the user of the AED 40, the manager of the receiver 80, and the like. A communication processing unit 48c that performs the communication, so that the user of the AED 40 advises the manager of the receiver 80 about the use of the AED 40 through the dialogue between the user of the AED 40 and the manager of the receiver 80, etc. Etc.

  The call processing unit 48c of the AED 40 communicates a signal including an image captured by the image capturing unit 47 to the receiver 80 via the wireless communication unit 44b, and the signal including the image transmitted from the receiver 80 is wireless. When the image is received via the communication unit 44b, the image is displayed on the display unit 46a, so that an image can be exchanged between the user of the AED 40 and the manager of the receiver 80 or the like. Therefore, for example, an administrator of the receiver 80 or the like can accurately grasp the surroundings of the AED 40 based on the image received from the AED 40. Further, it becomes possible for the user of the AED 40 to accurately grasp advice on the use of the AED 40 based on the image received from the receiver 80.

[Embodiment 2]
Next, the fire alarm system according to Embodiment 2 will be described. In the second embodiment, the control method of the fire alarm system is a P-type method. However, the configuration of the second embodiment is substantially the same as the configuration of the first embodiment unless otherwise specified. The configuration substantially the same as the configuration of the first embodiment is used in the first embodiment. The same reference numerals and / or names as those used are attached as necessary, and the description thereof is omitted.

(Constitution)
First, the configuration of the fire alarm system according to Embodiment 2 will be described. FIG. 13 is a schematic diagram illustrating a configuration of a fire alarm system according to Embodiment 2. FIG. 14 is a block diagram showing an electrical configuration of the composite notification device. As shown in FIGS. 13 and 14, the fire alarm system 101 includes a sensor 10, a composite alarm device 20, a receiver 80, and a notification device 90.

  The connection form of these devices is set as shown below. Specifically, for the connection between the receiver 80 and each of the sensor 10, the transmitter 30, and the AED 40, a system (so-called P-type system) that communicates a fire signal or the like as a common signal is adopted. Therefore, at least one sensor 10, transmitter 30, and AED 40 installed on each floor of the building are connected to the receiver 80 via the first wiring 2. Here, the configuration of the first wiring 2 is specifically configured to include three signal lines, and more specifically, the first wiring 2 includes an L line (not shown) and a C line. (Not shown) and A line (not shown) are included. Note that a predetermined voltage is applied from the receiver 80 between the L line and the C line and between the A line and the C line in the first wiring 2. Further, a termination (not shown) (for example, a resistor) is connected to each of the terminations of the L and C lines and the terminations of the A and C lines. The receiver 80 electrically determines whether or not these terminators are connected (for example, determines whether or not the current flowing from the L line to the C line via the terminator is within a predetermined range. ), It is determined whether the L line and C line (or A line and C line) are disconnected (or short-circuited).

  Regarding the connection between the receiver 80 and a device other than the sensor 10 and the transmitter 30, the display device 60 is connected to the receiver 80 via the second wiring 3, and the acoustic device 70. Is connected to the receiver 80 via the third wiring 4. The relay device 50 is connected to the receiver 80 via the fifth wiring 6, and the notification device 90 is connected to the receiver 80 via the sixth wiring 7.

(Configuration-combined notification device)
Next, the configuration of the composite notification device 20 will be described. As shown in FIG. 14, the composite notification device 20 is configured by integrally housing a transmitter 30, an AED 40, a relay device 50, a display device 60, and an acoustic device 70 inside a housing 21. ing.

(Configuration-Combined notification device-Relay device)
The relay device 50 includes a communication unit 51, a wireless communication unit 52, and a control unit 53. Among these, the communication unit 51 communicates with the receiver 80 via the fifth wiring 6.

(Configuration-Receiver)
Next, the configuration of the receiver 80 will be described. FIG. 15 is a block diagram showing an electrical configuration of the receiver 80. As illustrated in FIG. 15, the receiver 80 includes an operation unit 81, a communication unit 82, a display unit 83, a voice input unit 84, a voice output unit 85, a power supply unit 86, a control unit 87, and a storage unit 88. It is configured. Among these, the communication unit 82 includes an L-C input unit 82a and an AC input unit 82b. Here, the L-C input unit 82 a is an L-C input unit that inputs a signal transmitted from the sensor 10 or the transmitter 30 to the receiver 80 via the L line and the C line of the first wiring 2. is there. The AC input unit 82 b is an AC input unit that inputs a signal transmitted from the transmitter 30 to the receiver 80 via the A line and the C line of the first wiring 2.

(processing)
Next, fire notification processing, use state notification processing, failure state notification processing, and use necessary state notification processing executed by the fire notification system 101 configured as described above will be described. Note that the failure state notification process and the use necessary state notification process are the same as the failure state notification process and the use necessary state notification process according to Embodiment 1 described above, and thus description of the processes is omitted.

(Processing-Fire alarm processing)
First, the fire notification process will be described. FIG. 16 is a flowchart of the fire notification process related to the sensor 10 or the transmitter 30. FIG. 17 is a flowchart of a fire notification process related to the display device 60 or the audio device 70. Regarding the fire notification process according to the second embodiment, the contents of the fire notification process according to the first embodiment shown in FIGS. 5 and 6 are excluded, except for the contents of the processes of SA2 and SA4 in FIG. 16 and SB1 and SB3 in FIG. Since it is the same as each process, the description is abbreviate | omitted.

  As shown in FIG. 16, after the processing of SA1, in SA2, the control unit of the sensor 10 determined to have detected a fire in SA1 sends the fire signal to the communication unit and the first wiring 2, the receiver 80, and The data is transmitted to each display device 60 and each acoustic device 70 via the second wiring 3 (or the third wiring 4). In addition, the controller of the transmitter 30 that has been determined in SA1 that the fire signal transmission instruction has been received via the emergency button 31a transmits the fire signal to the communication unit and the first wiring 2, the receiver 80, and the second wiring. 3 (or the third wiring 4) is transmitted to each display device 60 and each acoustic device 70, and the confirmation indicator lamp is lit on.

Here, the transmission of the fire signal in the sensor 10 is arbitrary. Specifically, first, the control unit of the sensor 10 sends the fire signal to the receiver 80 via the communication unit and the first wiring 2. Specifically, when the A line, the L line, and the C line of the first wiring 2 are disconnected in a normal state, the L line and the C line are connected so as to be conductive. Send fire signal. Next, the control unit 87 of the receiver 80 receives the fire signal transmitted from the sensor 10 via the first wiring 2 and the L-C input unit 82a, and the received fire signal is transmitted to the communication unit 82, the first. It transmits to each display apparatus 60 and each acoustic apparatus 70 via 2 wiring 3 (or 3rd wiring 4).
In addition, the transmission of the fire signal and the display of the confirmation indicator lamp in the transmitter 30 are arbitrary. Specifically, the control unit of the transmitter 30 receives the fire signal via the communication unit and the first wiring 2. More specifically, when the A line, L line, and C line of the first wiring 2 are disconnected at the normal time, the L line and the C line are made conductive. Send fire signal by connecting. Further, the confirmation indicator lamp is turned on by connecting the A line so as to be conductive. Next, the control unit 87 of the receiver 80 receives the fire signal transmitted from the transmitter 30 via the first wiring 2, the L-C input unit 82a, and the AC input unit 82b, and the received fire. The signal is transmitted to each display device 60 and each acoustic device 70 via the communication unit 82 and the second wiring 3 (or the third wiring 4).
As for the connection state of the A line, the L line, and the C line of the first wiring 2 in SA2 described above, the control unit of the sensor 10 (or transmitter 30) to which the fire signal is transmitted in SA2 is changed to SA4. It continues until it shifts (that is, the fire signal is continuously transmitted until it shifts to SA4).

  Next, as shown in FIG. 17, in SB1, the control unit 63 of each display device 60 (or the control unit 73 of each acoustic device 70) detects the sensor 10 (or that is determined to have detected a fire in SA1) (or The fire signal transmitted from the transmitter 30) determined to have received the fire signal transmission instruction via the emergency button 31a in SA1 is the first wiring 2, the receiver 80, the second wiring 3 (or the third wiring). 4) and whether it is received via the communication unit 62 (or the communication unit 72).

  Returning to FIG. 16, after the processing of SA3, the controller of the sensor 10 that has been determined that the fire is no longer detected in SA3 in SA4 (or before the emergency button 31a accepts the fire signal transmission instruction in SA3). The control unit of the transmitter 30 determined to have been restored to the state is changed from the state in which the fire signal of the sensor 10 (or the transmitter 30) of SA2 is transmitted to the state before the transmission of the fire signal. In other words, the transmission of the fire signal by the communication unit is stopped (in the case of the transmitter 30, the display of the confirmation indicator lamp is also stopped). Here, the stop of the transmission of the fire signal in the sensor 10 is arbitrary, but in the second embodiment, when transmitting the fire signal, only the L line and the C line of the first wiring 2 are conducted. When connected, the transmission of the fire signal is stopped by disconnecting the L line and the C line so that a normal connection state is obtained. In addition, the transmission stop of the fire signal and the stop of the display of the confirmation indicator lamp in the transmitter 30 are arbitrary, but in the second embodiment, when the fire signal is transmitted and the confirmation indicator lamp is turned on, When A line, L line, and C line of 1 wiring 2 are connected so as to be conductive, by disconnecting these A line, L line, and C line so as to be in a normal connection state The transmission of the fire signal is stopped and the lighting display of the confirmation indicator lamp is stopped.

  Next, as shown in FIG. 17, in SB3, the control unit 63 of each display device 60 (or the control unit 73 of each acoustic device 70) determines that the sensor 10 (or that the fire is no longer detected in SA3) (or , The fire signal transmitted from the transmitter 30) determined that the emergency button 31a has been restored to the state before accepting the fire signal transmission instruction in SA3, the first wiring 2, the receiver 80, and the second wiring 3 It is determined whether or not the data is continuously received via (or the third wiring 4) and the communication unit 62 (or the communication unit 72). And when it is determined that the control unit 63 of each display device 60 (or the control unit 73 of each acoustic device 70) continuously receives the fire signal (SB3, Yes), the fire signal is continued. The process of SB3 is repeated until it is determined that the fire signal is not received, and when it is determined that the fire signal is not continuously received (SB3, No), the process proceeds to SB4.

(Processing-usage status notification process)
Next, the usage state notification process will be described. The usage state notification process according to the second embodiment is the same as each process of the usage state notification process according to the first embodiment, except for the contents of the processes of SC3 and SC5 in FIG. 7 and SD1 and SD3 in FIG. Therefore, the illustration and description of the flowchart are omitted.

  After the processing of SC2, the control unit 48 of the AED 40 that is determined to be in use in SC1 in SC3 sends the use state signal to the wireless communication unit 44b, the relay device 50, the fifth wiring 6, the receiver 80, the second The data is transmitted to each display device 60 and each acoustic device 70 via the wiring 3 (or the third wiring 4). In addition, when a process related to a voice call is performed between the user of the AED 40 and the manager of the receiver 80 immediately before or after performing the process of SC3, the receiver 80 in the AED 40 The communication is performed via the wireless communication unit 44b, the relay device 50, and the fifth wiring 6.

  Next, in SD1, the control unit 63 of each display device 60 (or the control unit 73 of each acoustic device 70) transmits the usage state signal transmitted from the AED 40 determined to be in the usage state in SC1 to the relay device 50. It is determined whether or not the signal has been received via the fifth wiring 6, the receiver 80, the second wiring 3 (or the third wiring 4), and the communication unit 62 (or the communication unit 72).

  In SC5, the control unit 48 of the AED 40 determined to be in the non-use state in SC4 sends the non-use state signal to the wireless communication unit 44b, the relay device 50, the fifth wiring 6, the receiver 80, and the second wiring. 3 (or the third wiring 4) to transmit to each display device 60 and each acoustic device 70.

  Next, in SD3, the control unit 63 of each display device 60 (or the control unit 73 of each acoustic device 70) relays the unused state signal transmitted from the AED 40 determined to be in the unused state in SC4. It is determined whether or not the signal is received via the fifth wiring 6, the receiver 80, the second wiring 3 (or the third wiring 4), and the communication unit 62 (or the communication unit 72).

(effect)
As described above, according to the second embodiment, even when the control method of the fire alarm system 101 is the P-type method, the AED 40 generates the state information indicating the state of the AED 40 based on the determination result of the determination unit 48a and the like. A wireless communication unit 44b that wirelessly communicates a signal including the signal to the wireless communication unit 52. The display device 60 or the acoustic device 70 receives a signal including state information transmitted from the wireless communication unit 44b via the wireless communication unit 52. When received, since the state information is output to the indicator lamp 61 or the emergency bell 71, even when the AED 40 is used in a place away from the wireless communication unit 52, the signal including the state information transmitted from the AED 40 Can be received by the display device 60 or the acoustic device 70 via the wireless communication unit 52, and the state information can be presented to the person in the building. Thereby, the person in the building can grasp the state of the AED 40 and can quickly take necessary measures according to the state of the AED 40 as compared with the conventional technique.

[III] Modifications to Embodiments Although the embodiments according to the present invention have been described above, the specific configuration and means of the present invention are within the scope of the technical idea of the present invention described in the claims. It can be arbitrarily modified and improved within. Hereinafter, such a modification will be described.

(About problems to be solved and effects of the invention)
First, the problems to be solved by the invention and the effects of the invention are not limited to the above contents, and may vary depending on the implementation environment and details of the configuration of the invention. May be solved, or only some of the effects described above may be achieved. For example, even if the state of the AED 40 cannot be notified to a person in a building than the conventional system, the conventional system is to notify the state of the AED 40 to the same extent as the conventional system. If it can be achieved by a different system of the present invention, the problem of the present invention has been solved.

(About distribution and integration)
Further, each of the electrical components described above is functionally conceptual and does not necessarily need to be physically configured as illustrated. In other words, the specific forms of distribution and integration of each unit are not limited to those shown in the drawings, and all or a part thereof may be functionally or physically distributed or integrated in arbitrary units according to various loads or usage conditions. Can be configured. For example, the AED 40, the relay device 50, the display device 60, the acoustic device 70, and the receiver 80 may be configured to be distributed among a plurality of devices, or the AED 40, the relay device 50, the display device 60, the acoustic device 70, and the receiver 80. A part of one function may be given to the other. Further, in the case of distributing each part, the cooperation between these parts can be performed by one or both of wired and wireless.

(Interrelation between the embodiments)
In the case where a plurality of embodiments are described, between the plurality of embodiments, a part of the configuration or processing may be interchanged, or one configuration or processing may be applied to the other. May be.

(About shape, numerical value, structure, time series)
Regarding the constituent elements illustrated in the embodiments and drawings, the shape, numerical value, or the structure or mutual relationship of a plurality of constituent elements are arbitrarily modified and improved within the scope of the technical idea of the present invention. be able to.

(Fire information output device)
In the first and second embodiments, the fire information output device is described as the display device 60 and the acoustic device 70. However, the fire information output device is not limited to this, and may be, for example, the sensor 10 or the like. Here, regarding the output of the state information of the sensor 10, specifically, the sensor 10 wirelessly communicates with the AED 40 via a wireless antenna (not shown) (first wireless communication unit). Communication means) and a display unit (display means) for displaying fire information, and when the control unit of the sensor 10 receives a status signal including status information from the AED 40 via the wireless communication unit, The state information included in the state signal is displayed on this display unit.

(About the combined notification device)
In the first and second embodiments, the composite notification device 20 integrally accommodates the transmitter 30, the AED 40, the relay device 50, the display device 60, and the acoustic device 70 inside the housing 21. Although described as being configured, it is not limited to this. For example, in addition to these devices, other devices and facilities (for example, a fire hydrant) may be integrally accommodated.

  In the first and second embodiments, it has been described that the composite notification device 20 includes the display device 60 and the acoustic device 70. However, the present invention is not limited to this. Only one of them may be provided.

(About AED)
In the first and second embodiments, the AED 40 includes the voice input unit 46b, the voice output unit 46c, and the call processing unit 48c so that the user of the AED 40 and the manager of the receiver 80 can interact with each other. However, the present invention is not limited to this. For example, the voice input unit 46b, the voice output unit 46c, and the call processing unit 48c may be omitted.

  In the first and second embodiments, communication between the AED 40 and the receiver 80 is performed by the wireless communication unit 44b, the relay device 50, and the relay so that the user of the AED 40 and the administrator of the receiver 80 can interact with each other. Although it has been described that the process is performed via the fourth wiring 5 (or the fifth wiring 6), the present invention is not limited to this. For example, the communication with the center device in the AED 40 is performed by the wireless communication unit 44b, the relay device 50, the fourth wiring 5 so that the user of the AED 40 and the manager of the center device installed in the fire department can communicate. (Or the fifth wiring 6), the receiver 80, and an external communication network.

(About audio equipment)
In the first and second embodiments, it has been described that the acoustic device 70 includes the emergency bell 71. However, the present invention is not limited to this. For example, a known buzzer or a known speaker may be provided so that fire information or state information can be output with various timbres. Here, the output of fire information and status information by a buzzer or speaker is optional, but for example, as a fire information output, a standard message such as “Fire has occurred” is output, and status information (here, A standard message such as “AED is being used” may be output as the output of usage status information.

(About fire alarm processing)
In the first and second embodiments, it has been described that in the output of fire information in SB2, the indicator lamp 61 of the display device 60 is turned on and the bell sound is continuously output by the emergency bell 71 of the acoustic device 70. Not limited to this. For example, the display lamp 61 blinks at a time interval (for example, 1 sec interval) different from the display of the usage state information by the indicator lamp 61, and a time interval (for example, different from the fire information output by the emergency bell 71). The emergency bell 71 may intermittently output a “buzzing” bell sound at intervals of 1 sec.

(About usage status notification processing)
In the first embodiment, in SC3, the control unit 48 of the AED 40 determined to be in use in SC1 sends the use state signal to the wireless communication unit 44b, the relay device 50, the first wiring 2, the receiver 80, Although it demonstrated that it transmitted to each display apparatus 60 and each acoustic apparatus 70 via the 2nd wiring 3 (or 3rd wiring 4), it is not restricted to this. For example, in order to output only the usage status information to the display device 60 and the acoustic device 70 accommodated in the casing 21 in which the AED 40 is accommodated, the control unit 48 of the AED 40 transmits the usage status signal to the wireless communication unit 44b, You may transmit only to the display apparatus 60 and the said audio apparatus 70 which were mentioned above via the relay apparatus 50 and the 4th wiring 5. FIG. In this case, in SC6, the control unit 48 of the AED 40 determined to be in the non-use state in SC5 sends the non-use state signal to the above-described signal via the wireless communication unit 44b, the relay device 50, and the fourth wiring 5. It transmits only to the display device 60 and the acoustic device 70 that have been used. By such processing, the use state information is obtained only by the indicator lamp 61 of the display device 60 or the emergency bell 71 of the acoustic device 70 accommodated in the casing 21 in which the AED 40 determined to be in use by the SC 1 is accommodated. Therefore, the person in the building can easily and accurately recognize the AED 40 in use from among the plurality of AEDs 40 installed in the building.

  In Embodiments 1 and 2 described above, in SD2, SF2, and SH2, the control unit 63 of the display device 60 causes the indicator lamp 61 to blink and display at a predetermined time interval. However, the present invention is not limited to this. For example, the indicator lamp 61 includes a red LED lamp, a white LED lamp, a yellow LED lamp, and a green LED lamp so that the display lamp 61 can display fire information and status information in different display colors. With. Then, the control unit 63 of the display device 60 causes the fire information to be output by the red LED lamp, causes the use state information to be output by the white LED lamp, causes the failure state information to be output by the yellow LED lamp, and uses necessary state information. May be output by a green LED lamp.

(About failure status notification processing)
In the first embodiment, in SE2 (or SE4), the control unit 48 of the AED 40 sends a failure state signal (or failure state restoration signal) via the wireless communication unit 44b, the relay device 50, and the fourth wiring 5. Although it has been described that transmission is performed to the display device 60 and the acoustic device 70 accommodated in the casing 21 in which the AED 40 is accommodated, the present invention is not limited thereto. For example, the display device 60 and the acoustic device 70 described above are configured to transmit a failure state signal (or failure state restoration signal) via the communication unit 44a, the first wiring 2, the receiver 80, and the second wiring 3 (or the third wiring 4). May be sent only to Specifically, first, the control unit 48 of the AED 40 adds a communication unit 44a and a communication unit 44a to which the identification information uniquely identifying the AED 40 stored in the storage unit 49 is added to the failure state signal (or failure state recovery signal). The data is transmitted to the receiver 80 via one wiring 2. Next, the control unit 87 of the receiver 80 receives the failure state signal (or failure state restoration signal) transmitted from the AED 40 via the first wiring 2 and the communication unit 82. Next, the control unit 87 of the receiver 80 is based on the identification information added to the received failure state signal (or failure state restoration signal), and the display device 60 (or the acoustic device) described above installed near the AED 40. 70) and a failure state signal (or failure state restoration signal) is transmitted only to the specified display device 60 (or acoustic device 70) via the communication unit 82 and the second wiring 3 (or third wiring 4). (The same applies to the transmission of the use necessary state signal (or use unnecessary state signal) of the use necessary state notification process according to the first embodiment). Thereby, without using the 4th wiring 5, a failure state signal (or failure state restoration signal) can be transmitted only to the display apparatus 60 (or acoustic apparatus 70) mentioned above, and the display apparatus 60 (or acoustic apparatus 70) mentioned above. Only the failure state information can be output or the output of the failure state information can be stopped. In this case, the fourth wiring 5 can be omitted.

(Appendix)
In order to solve the above-described problems and achieve the object, the fire alarm system according to supplementary note 1 is a fire alarm system that detects a fire in a monitoring area and gives an alarm, and outputs fire information indicating the fire alarm A fire information output device that outputs by, an automatic external defibrillator that performs defibrillation, and first wireless communication means that performs wireless communication between the automatic external defibrillator, and The automatic external defibrillator is a determination means for determining the state of the automatic external defibrillator, and state information indicating the state of the automatic external defibrillator based on the determination result of the determination means. And a second wireless communication means for wirelessly communicating a signal including the first wireless communication means, wherein the fire information output device receives the signal including the state information transmitted from the second wireless communication means. When received via the first wireless communication means And outputs the state information to said output means.

  The fire alarm system according to appendix 2 is the fire alarm system according to appendix 1, including the use state of the automatic external defibrillator as the state of the automatic external defibrillator, and the automatic external defibrillator. The second wireless communication means of the mover indicates that the automatic external defibrillator is in use when the determination means determines that the automatic external defibrillator is in use. A signal including the state information is communicated wirelessly to the first wireless communication means.

  The fire alarm system according to appendix 3 is the fire alarm system according to appendix 1 or 2, wherein the state of the automatic external defibrillator includes a failure state of the automatic external defibrillator, and the automatic external system The second wireless communication means of the defibrillator is in a state where the automatic external defibrillator is in a failure state when the determination means determines that the automatic external defibrillator is in a failure state. A signal including the state information indicating the fact is communicated wirelessly to the first wireless communication means.

  The fire alarm system according to appendix 4 requires the use of the automatic external defibrillator as the state of the automatic external defibrillator in the fire alarm system according to any one of appendices 1 to 3. The second wireless communication means of the automatic external defibrillator includes the necessary use state, and when the determination means determines that the automatic external defibrillator is in the use required state, A signal including the state information indicating that the automatic external defibrillator is in a use-needed state is wirelessly communicated to the first wireless communication means.

  The fire alarm system according to appendix 5 is the fire alarm system according to any one of appendices 1 to 4, and includes, as the fire information output device, a display device that displays the fire information with a display means. When the signal including the state information transmitted from the second wireless communication unit is received via the first wireless communication unit, the state information is displayed on the display unit.

  The fire alarm system according to appendix 6, in the fire alarm system according to any one of appendices 1 to 5, includes an acoustic device that outputs the fire information as an alarm sound by an alarm sound output means as the fire information output device. When the signal including the state information transmitted from the second wireless communication unit is received via the first wireless communication unit, the acoustic device causes the alarm sound output unit to output the state information. .

  The fire alarm system according to appendix 7, in the fire alarm system according to any one of appendices 1 to 6, wherein the automatic external defibrillator receives a communication stop instruction for receiving a communication stop signal including the state information The second wireless communication unit of the automatic external defibrillator includes an operation unit, and when the instruction to stop communication of the signal including the state information is received via the communication stop operation unit, Stops communication of signals that contain information.

  The fire alarm system according to appendix 8 is the fire alarm system according to any one of appendices 1 to 7, wherein the automatic external defibrillator is different from the other apparatus different from the automatic external defibrillator. Voice input means for inputting voice, voice output means for outputting voice, a user of the automatic external defibrillator, and a user of the other device And call processing means for performing processing related to a call performed by voice.

  The fire alarm system according to appendix 9, in the fire alarm system according to any one of appendices 1 to 8, wherein the automatic external defibrillator is connected to the other device so as to be able to communicate with each other. An image pickup means for picking up an image around the automatic external defibrillator or an image display means for displaying an image, wherein the call processing means of the automatic external defibrillator is configured to pick up the image. A signal including an image captured by the means is communicated to the other apparatus via the second wireless communication means, or a signal including an image transmitted from the other apparatus is transmitted to the second wireless communication means. The image is displayed on the image display means.

  The automatic external defibrillator according to appendix 10 is an automatic external defibrillator that performs defibrillation, a determination unit that determines a state of the automatic external defibrillator, and a first wireless communication unit A second wireless communication unit that performs wireless communication with the first wireless communication unit, based on a determination result of the determination unit, a signal including state information indicating a state of the automatic external defibrillator And a second wireless communication means for transmitting to the fire information output device for outputting fire information indicating fire notification via the means.

(Additional effects)
According to the fire alarm system described in appendix 1, the automatic external defibrillator receives the first signal including state information indicating the state of the automatic external defibrillator based on the determination result of the determination unit. A second wireless communication means for wirelessly communicating with the wireless communication means, and the fire information output device receives a signal including the state information transmitted from the second wireless communication means via the first wireless communication means. If the automatic external defibrillator is used at a location away from the first wireless communication means, the status information is output from the automatic external defibrillator. The fire information output device can receive a signal including the state information via the first wireless communication means, and the state information can be presented to the person in the monitoring area. As a result, people in the monitoring area can grasp the state of the automatic external defibrillator and can take necessary measures according to the state of the automatic external defibrillator more quickly than the conventional technology. It becomes. In addition, since the fire information and state information are output by the output means of the fire information output device, for example, compared with the case where output means for outputting only fire information and output means for outputting only state information are provided respectively. Thus, the installation space can be reduced and the installation space can be made compact.

  According to the fire alarm system described in appendix 2, when the second wireless communication unit determines that the automatic external defibrillator is in use by the determination unit, the automatic external defibrillator is A state indicating that the automatic external defibrillator is in use for a person in the monitoring area because a signal including state information indicating that it is in use is wirelessly communicated to the first wireless communication means. Information can be presented. This allows people in the surveillance area to know that the automated external defibrillator is in use, and to perform lifesaving activities for people whose heart has become unable to beat normally In addition, when an automatic external defibrillator is used, the user of the automatic external defibrillator can easily receive life support from a third party other than the user quickly. .

  According to the fire alarm system described in appendix 3, when the second wireless communication unit determines that the automatic external defibrillator is in a failure state by the determination unit, the automatic external defibrillator is A state indicating that the automatic external defibrillator is in a failure state for a person in the monitoring area because a signal including state information indicating that the failure is in a state is communicated wirelessly to the first wireless communication means. Information can be presented. Thereby, a person in the monitoring area can grasp that the automatic external defibrillator is in a failure state, and can quickly inspect and repair the automatic external defibrillator.

  According to the fire alarm system described in Appendix 4, when the second wireless communication unit determines that the automatic external defibrillator is in a use-necessary state by the determination unit, the automatic external defibrillator Since the signal including the state information indicating that the device is in the use-necessary state is wirelessly communicated to the first wireless communication means, the automatic external defibrillator is in the use-necessary state for the person in the monitoring area. It is possible to present status information indicating Thereby, the person in the monitoring area can grasp that the automatic external defibrillator is in a use-needed state, and can use the automatic external defibrillator quickly.

  According to the fire alarm system described in appendix 5, the display device displays the state information when a signal including the state information transmitted from the second wireless communication unit is received via the first wireless communication unit. Since the information is displayed on the means, the state information can be displayed on the display means and presented to the person in the monitoring area, and the state information can be easily and reliably transmitted to the person in the monitoring area.

  According to the fire alarm system described in appendix 6, when the acoustic device receives a signal including the state information transmitted from the second wireless communication unit via the first wireless communication unit, the sound device alerts the state information. Since it is made to output to a sound output means, a state information can be shown through hearing with respect to the person in a monitoring area | region. Therefore, when the person in the monitoring area is at a position where the output means cannot be seen, or when the output means can be seen, it is difficult to see the information displayed on the output means. However, it is possible to quickly convey the state information.

  According to the fire alarm system described in Appendix 7, when the second wireless communication unit of the automatic external defibrillator receives an instruction to stop communication of a signal including state information via the communication stop operation unit Since the communication of the signal including the state information is stopped, the state information is output by the output means of the fire information output device when the administrator of the fire alarm system etc. checks the automatic external defibrillator. Since this can be avoided, status information can be prevented from being erroneously output even though the automatic external defibrillator is not used.

  According to the fire alarm system described in appendix 8, the automatic external defibrillator includes voice input means for inputting voice, voice output means for outputting voice, and a user of the automatic external defibrillator; Call processing means for performing processing related to a call performed by voice with a user of another device, and through interaction between the user of the automatic external defibrillator and the user of the other device, Users of automatic external defibrillators can receive advice on the use of automatic external defibrillators from users of other devices.

  According to the fire alarm system described in appendix 9, the call processing unit of the automatic external defibrillator communicates a signal including an image captured by the imaging unit to another device via the second wireless communication unit. Alternatively, when a signal including an image transmitted from another device is received via the second wireless communication unit, the image is displayed on the image display unit. Therefore, the user of the automatic external defibrillator Can exchange images with each other and users of other devices. Therefore, for example, a user of another device can accurately grasp the situation around the automatic external defibrillator based on the image received from the automatic external defibrillator. Alternatively, the user of the automatic external defibrillator can accurately grasp advice on the use of the automatic external defibrillator based on the image received from another device.

  According to the automatic external defibrillator described in appendix 10, it is the second wireless communication unit that performs wireless communication with the first wireless communication unit, and based on the determination result of the determination unit, the automatic external type defibrillator Since the second wireless communication means for transmitting the signal including the state information indicating the state of the defibrillator to the fire information output device that outputs the fire information indicating the fire notification via the first wireless communication means, Even when the automatic external defibrillator is used at a location away from the first wireless communication means, a signal including state information can be transmitted to the fire information output device via the first wireless communication means. It is possible to present status information to a person who is present. As a result, people in the monitoring area can grasp the state of the automatic external defibrillator and can take necessary measures according to the state of the automatic external defibrillator more quickly than the conventional technology. It becomes. In addition, since the fire information and state information are output by the output means of the fire information output device, for example, compared with the case where output means for outputting only fire information and output means for outputting only state information are provided respectively. Thus, the installation space can be reduced and the installation space can be made compact.

DESCRIPTION OF SYMBOLS 1 Fire alarm system 2 1st wiring 3 2nd wiring 4 3rd wiring 5 4th wiring 6 5th wiring 7 6th wiring 10 Sensor 20 Composite alarm device 21 Housing | casing 22a Base part 22b Upper front panel part 22c Lower front panel Part 23a First operation port 23b Second operation port 23c Sound hole 23d Light guide hole 23e Door part 23f Door window part 30 Transmitter 31a Emergency button 31b Recovery button 40 AED
41 AED main body unit 42 operation unit 42a communication stop button 43 detection unit 44a communication unit 44b wireless communication unit 45 power supply unit 46a display unit 46b audio input unit 46c audio output unit 47 imaging unit 48 control unit 48a determination unit 48b image processing unit 48c call Processing unit 49 Storage unit 50 Relay device 51 Communication unit 52 Wireless communication unit 53 Control unit 60 Display device 61 Indicator light 62 Communication unit 63 Control unit 70 Acoustic device 71 Emergency bell 72 Communication unit 73 Control unit 80 Receiver 81 Operation unit 82 Communication Unit 82a LC input unit 82b AC input unit 83 display unit 84 voice input unit 85 voice output unit 86 power supply unit 87 control unit 87a call processing unit 88 storage unit 90 reporting device 101 fire notification system

Claims (10)

A fire alarm system that detects and alerts a fire in a monitoring area,
A fire information output device for outputting fire information indicating a fire notification by an output means;
An automatic external defibrillator that performs defibrillation,
First wireless communication means for performing wireless communication with the automatic external defibrillator,
The automatic external defibrillator is:
Determining means for determining the state of the automatic external defibrillator;
A second wireless communication unit that wirelessly communicates a signal including state information indicating the state of the automatic external defibrillator to the first wireless communication unit based on a determination result of the determination unit;
The fire information output device is:
When the signal including the state information transmitted from the second wireless communication unit is received via the first wireless communication unit, the state information is output to the output unit.
Fire alarm system. As the state of the automatic external defibrillator, including the use state of the automatic external defibrillator,
The second wireless communication means of the automatic external defibrillator is:
When the determination means determines that the automatic external defibrillator is in use, a signal including the state information indicating that the automatic external defibrillator is in use is the first signal. Communicate wirelessly to wireless communication means,
The fire alarm system according to claim 1. As the state of the automatic external defibrillator, including a failure state of the automatic external defibrillator,
The second wireless communication means of the automatic external defibrillator is:
If the determination means determines that the automatic external defibrillator is in a failure state, a signal including the state information indicating that the automatic external defibrillator is in a failure state is output from the first signal. Communicate wirelessly to wireless communication means,
The fire alarm system according to claim 1 or 2. As the state of the automatic external defibrillator, including a use required state that requires use of the automatic external defibrillator,
The second wireless communication means of the automatic external defibrillator is:
When the determination means determines that the automatic external defibrillator is in a use-necessary state, the signal including the state information indicating that the automatic external defibrillator is in a use-necessary state Communicating wirelessly with the first wireless communication means;
The fire alarm system according to any one of claims 1 to 3. As the fire information output device, comprising a display device for displaying the fire information by display means,
The display device
When a signal including the state information transmitted from the second wireless communication unit is received via the first wireless communication unit, the state information is displayed on the display unit.
The fire alarm system according to any one of claims 1 to 4. As the fire information output device, comprising an acoustic device that outputs the fire information with an alarm sound by an alarm sound output means,
The acoustic device is
When the signal including the state information transmitted from the second wireless communication unit is received via the first wireless communication unit, the state information is output to the alarm sound output unit.
The fire alarm system according to any one of claims 1 to 5. The automatic external defibrillator is:
Communication stop operation means for receiving an instruction to stop communication of a signal including the state information,
The second wireless communication means of the automatic external defibrillator is:
When an instruction to stop communication of the signal including the state information is received via the communication stop operation unit, the communication of the signal including the state information is stopped.
The fire alarm system according to any one of claims 1 to 6. The automatic external defibrillator is:
The automatic external defibrillator is connected so as to be able to communicate with other devices different from each other,
Voice input means for inputting voice;
Audio output means for outputting audio;
Call processing means for performing processing related to a call performed by voice between the user of the automatic external defibrillator and the user of the other device,
The fire alarm system according to any one of claims 1 to 7. The automatic external defibrillator is:
The other devices are connected to be able to communicate with each other,
An image pickup means for picking up an image around the automatic external defibrillator, or an image display means for displaying an image,
The call processing means of the automatic external defibrillator is:
A signal including an image captured by the imaging unit is communicated to the other device via the second wireless communication unit; or
When a signal including an image transmitted from the other device is received via the second wireless communication unit, the image display unit displays the image.
The fire alarm system according to claim 8. An automatic external defibrillator that performs defibrillation,
Determining means for determining the state of the automatic external defibrillator;
A second wireless communication means for performing wireless communication with the first wireless communication means, and based on a determination result of the determination means, a signal including state information indicating a state of the automatic external defibrillator, Second wireless communication means for transmitting to a fire information output device for outputting fire information indicating fire notification via the first wireless communication means;
Automatic external defibrillator equipped with

Images