JP2017117144A - Program, terminal device and fire alarm system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a program for a terminal device, terminal device and fire alarm system that allow quick measures to be taken when a fire occurs or the fire is likely to occur.SOLUTION: In a terminal device included in a fire alarm system to be installed in a building for automatically alarming a fire occurring in the building, first acquisition processing and first display processing are executed. The first acquisition processing, when the occurrence of the fire is detected by a fire sensor installed in the building, acquires fire location information indicative of a fire sensing location having the fire sensor sensing the fire installed via a communication unit of the terminal device to be connected to a network installed in the building. In the first display processing is processing to, when the fire location information is acquired, cause a display unit of the terminal device to display a floor map of the building having the fire sensing location included.SELECTED DRAWING: Figure 5

Description

  The present invention relates to a program for causing a control unit that controls a terminal device included in a fire alarm system installed in a building to automatically notify a fire that has occurred in a building to execute a predetermined process, a terminal device, and a fire alarm system. .

  Technologies related to fire alarms have been proposed. For example, Patent Document 1 discloses an equipment management apparatus. In the facility management apparatus, the display control means receives the event detection signal output from the event detection means. The event detection signal indicates that an event such as a fire has occurred. The display control means retrieves the tunnel background image corresponding to the event occurrence position from the tunnel background image storage means and displays it on the display screen of the display means. Further, the display control means superimposes and displays the facilities existing in the displayed tunnel background image on the displayed tunnel background image by a pictorial display. The aforementioned facility is, for example, an evacuation pit. When the operator wants to know the detailed information of the equipment displayed as a picture, the operator selects and designates the picture display using the selection means. The display control means determines the type of equipment requested from the designated picture display. The display control means superimposes and displays the still image representing the appearance of the equipment, the installation position of the kilometer post, and the specifications of the equipment on the tunnel background image in a window manner. As the selection means, a touch panel or a tablet arranged on the display screen of the display means is used. In Patent Document 1, the facility management apparatus is generated in a tower facility having a relatively large-capacity high-rise building, an amusement hall facility such as a movie theater with a large capacity, or an observation room provided at a high position. It is also possible to adopt a configuration corresponding to various accidents including fire.

JP-A-9-154124

  Fire detectors, fire receivers and alarm outputs may be installed in buildings. The fire receiver is installed, for example, in one room (for example, a management room or a guard room) in a building that serves as a security or monitoring base for the building. Examples of the alarm output machine include emergency broadcast equipment and district sound equipment (emergency bell). When a fire detector detects a fire, the fire receiver sounds an alarm output device. A person in the building can know the occurrence of a fire by an alarm sound. The inventor shall further provide a place where a fire has occurred to a security guard or a supervisor who is away from the above-mentioned place serving as a base for security or monitoring of a building in a situation where a fire has occurred or is suspected. Or, a technology that can notify the location where a fire may have occurred was examined.

  An object of the present invention is to provide a program for a terminal device, a terminal device, and a fire alarm system that enable a quick response when a fire has occurred or when a fire may have occurred.

  One aspect of the present invention provides a control unit that controls a terminal device included in a fire alarm system installed in the building that automatically notifies of a fire that has occurred in a building, with a fire detector installed in the building. When the occurrence is detected, the fire location information indicating the fire detection location where the fire detector that has detected the fire is installed is acquired via the communication unit of the terminal device connected to the network installed in the building. A first acquisition process for performing the first display process for displaying the floor map of the building including the fire detection location on the display unit of the terminal device when the fire location information is acquired. is there. According to this program, when the occurrence of a fire is detected by the fire detector, the floor map including the fire detection location can be displayed on the display unit. The user of the terminal device can consider the response to the fire based on the floor map displayed on the display unit.

  The program causes the control unit to display, on the display unit, the fire location information and map display operation information corresponding to the display of the floor map when the fire location information is acquired. And a second acquisition process of acquiring a floor map instruction for instructing display of the floor map via the operation unit of the terminal device in a state where the map display operation information is displayed on the display unit. The first display process may be executed when the fire place information and the floor map instruction are acquired. According to this configuration, the fire place information and the map display operation information can be displayed on the display unit. A floor map instruction can be acquired in accordance with the display of the map display operation information on the display unit, and the floor map can be displayed. The user of the terminal device can recognize the fire detection location based on the fire location information and display the floor map.

  In the second display process, when the fire location information is acquired, an alarm output from an alarm device installed in the building that outputs an alarm sound in response to the occurrence of a fire detected by the fire detector This is a process for further displaying stop operation information corresponding to sound stop on the display unit, and the program is displayed on the display unit with the stop operation information being displayed on the display unit. A third acquisition process for acquiring a stop instruction for instructing to stop an alarm sound output from the operation unit, and when the stop instruction is acquired, the stop instruction is transmitted from the communication unit to the alarm device. The first transmission process to be executed may be executed. According to this configuration, a stop instruction can be acquired in accordance with the display of the stop operation information on the display unit, and the stop instruction can be transmitted to the alarm device. Therefore, the alarm sound being output by the alarm device can be stopped from the terminal device. It is possible to avoid a state in which an alarm sound continues to sound. For example, when a fire detector malfunctions, the alarm sound can be easily stopped.

  In the second display process, when the fire location information is acquired, emergency call operation information corresponding to execution of an emergency call from a fire reporting device installed in the building to a fire department having jurisdiction over the location of the building is displayed. The program is further displayed on the display unit, and the program instructs the control unit to execute an emergency call on the fire notification device in a state where the emergency call operation information is displayed on the display unit. A fourth acquisition process for acquiring a notification instruction via the operation unit, and a second transmission process for transmitting the notification instruction from the communication unit to the fire notification device when the notification instruction is acquired. You may make it perform. According to this configuration, it is possible to acquire a notification instruction according to the display of the emergency notification operation information on the display unit, and transmit the notification instruction to the fire notification device. Therefore, the emergency notification from the fire notification device to the fire engine can be executed from the terminal device. Prompt emergency call is possible.

  The program, via the operation unit of the terminal device, gives an area instruction for designating a predetermined location of the building in the floor map in a state where the floor map is displayed on the display unit. And a fifth display process for acquiring the disaster information corresponding to the identification of the number of disaster victims in the predetermined place when the area instruction is acquired, In a state where the disaster information is displayed on the display unit, a sixth acquisition process for acquiring a disaster victim value indicating the number of the disaster victims via the operation unit, and when the disaster victim value is acquired, And executing a third transmission process for transmitting rescue information including the disaster victim value and designated location information indicating the predetermined location from the communication unit to a server device connected to the network. May be. According to this configuration, the area instruction can be acquired according to the display of the floor map, and the disaster information can be displayed on the display unit. And a disaster victim value can be acquired according to the display of disaster information, and rescue information can be transmitted to a server apparatus. Accordingly, by accessing the server device, a plurality of persons can share the number of victims and the location where the victims are located. Smooth rescue operations are possible.

  The first display processing includes facility information indicating disaster prevention equipment including at least one of a fire door, an emergency staircase, a digester, and a fire hydrant installed in the building, and route information indicating an evacuation route from a fire detection location. And the floor map including one or both of them may be displayed on the display unit. According to this configuration, a floor map including facility information and / or an evacuation route can be displayed. The user of the terminal device can understand the type and position of the disaster prevention facility and / or the evacuation route based on the floor map displayed on the display unit.

  Another aspect of the present invention is a terminal device included in a fire alarm system installed in the building that automatically notifies of a fire that has occurred in a building, and a communication unit connected to a network installed in the building When the occurrence of a fire is detected by the fire detector installed in the building, the fire location information indicating the fire detection location where the fire detector that detected the fire is installed is acquired via the communication unit. A terminal comprising: a first acquisition processing unit; a display unit; and a first display processing unit that causes the display unit to display a floor map of the building including the fire detection location when the fire location information is acquired. Device.

  Still another aspect of the present invention is a fire alarm system installed in the building that includes a fire receiving device and a terminal device connected via a network and automatically notifies of a fire that has occurred in a building, The fire receiving device transmits, when the occurrence of a fire is detected by a fire detector installed in the building, transmits fire location information indicating a fire detection location where the fire detector that detects the fire is installed, A second communication unit connected to the network, a first acquisition processing unit for acquiring the fire location information via the second communication unit, A fire alarm system comprising: a display unit; and a first display processing unit that causes the display unit to display a floor map of the building including the fire detection location when the fire location information is acquired.

  According to this terminal device and this fire alarm system, when the occurrence of a fire is detected by a fire detector, a floor map including a fire detection location can be displayed on the display unit. The user of the terminal device can consider the response to the fire based on the floor map displayed on the display unit. This terminal device or the terminal device in this fire alarm system can also be specified as a terminal device having a configuration corresponding to the predetermined processing of each program described above. In this case, the terminal device or the fire alarm system has the same operation as the corresponding program among the above programs.

  ADVANTAGE OF THE INVENTION According to this invention, the program for terminal devices, a terminal device, and a fire alerting | reporting system which can respond promptly when a fire has occurred or a fire may have occurred can be obtained.

It is a figure which shows an example of schematic structure of the building in which the fire alarm system and the fire alarm system were installed. It is a flowchart of the 1st part of the main process performed with a terminal device. It is a flowchart of the 2nd part of a main process. It is a flowchart of the 3rd part of a main process. It is a figure which shows an example of the screen displayed on a terminal device by the main process. The top row shows an example of the fire information screen. The lower part shows an example of the floor map screen displayed when the map display button is pressed while the fire information screen shown in the upper part is displayed. It is a figure which shows an example of the damage information screen displayed on a terminal device by the main process. The disaster information screen shown in FIG. 6 corresponds to a case where a predetermined position of the second floor room D is pressed while the floor map screen shown in the lower part of FIG. 5 is displayed.

  Embodiments for carrying out the present invention will be described with reference to the drawings. The present invention is not limited to the configurations described below, and various configurations can be employed in the same technical idea. For example, some of the configurations shown below may be omitted or replaced with other configurations. Other configurations may be included.

<Overall configuration of fire alarm system and building>
The overall configuration of the fire alarm system 1 and the building 2 will be described with reference to FIG. The fire alarm system 1 is installed in a building 2 together with a fire detector 70, an alarm device 80, and a fire alarm device 90. The fire alarm system 1 constructs a disaster prevention system for the building 2 together with the fire detector 70, the alarm device 80, and the fire alarm device 90. Examples of the building 2 include various facilities such as public facilities and commercial facilities. The various facilities include, for example, nursing care facilities, hospitals, schools, offices, stores, and factories. In addition, the building 2 is exemplified by a building and a condominium. That is, the building 2 targeted in the embodiment includes various buildings. A network 3 is installed in the building 2. An example of the network 3 is a LAN (Local Area Network). Each device connected to the network 3 is communicably connected via the network 3. The network 3 is connected to the Internet 4 via a gateway device. In FIG. 1, the gateway device is not shown. The fire notification system 1 includes a fire receiving device 10 and a terminal device 20, and automatically notifies a fire that has occurred in the building 2.

  The fire receiving device 10 includes a fire receiver 11 and a first sequencer 12. In the fire receiving device 10, the fire receiver 11 and the first sequencer 12 are wired by a predetermined communication cable. However, the connection between the fire receiver 11 and the first sequencer 12 may be a wireless connection. The fire receiver 11 is communicably connected to the fire detector 70. The fire receiver 11 is communicably connected to an alarm output device 81 of an alarm device 80 described later. The connection between the fire receiver 11 and the fire detector 70 is a wired connection. The connection between the fire receiver 11 and the alarm output device 81 is a wired connection. However, the connection between the fire receiver 11 and the fire detector 70 and / or the connection between the fire receiver 11 and the alarm output device 81 may be a wireless connection. As a result, the fire receiving device 10 can communicate with the fire detector 70 and the alarm device 80.

  The first sequencer 12 includes, for example, a CPU 13, a ROM (flash memory), a RAM, and a communication unit 14. In FIG. 1, illustration of ROM and RAM is omitted. The CPU 13 executes a program stored in the ROM using the RAM. The CPU 13 constitutes a control unit that controls the first sequencer 12. The communication unit 14 connects the first sequencer 12 to the network 3 and performs communication via the network 3. Thereby, the fire receiving device 10 can communicate with the server device 60 via the communication unit 14. In the fire receiving device 10, the fire place information is transmitted from the communication unit 14 to the server device 60. The description regarding this point will be described later. The fire place information will also be described later. A known fire receiver is used as the fire receiver 11. Known fire receivers are classified into, for example, P type (1st and 2nd class), R type, and GR type. Furthermore, a P-type receiver with an automatic test function is also known as a fire receiver. The model of the fire receiver 11 is appropriately determined in consideration of various circumstances. The first sequencer 12 is the same as a known sequencer in terms of hardware, and can be configured using a known sequencer. Therefore, the other description regarding the fire receiver 11 and the first sequencer 12 will be omitted as appropriate.

  The terminal device 20 is an information processing device having a communication function via the network 3. The terminal device 20 is, for example, a portable information processing device. Examples of the portable information processing apparatus include a tablet terminal, a smartphone, and a laptop computer. In the embodiment, the terminal device 20 is a tablet terminal. The connection of the terminal device 20 to the network 3 is a wireless connection. Examples of the wireless connection include connection by wireless LAN communication. The terminal device 20 is the same as a known tablet terminal in hardware. The other description regarding the terminal device 20 is mentioned later.

  The server device 60 is connected to the network 3. The server device 60 can communicate with the first sequencer 12, the terminal device 20, the second sequencer 82 of the alarm device 80 described later, and the third sequencer 92 of the fire notification device 90 described later connected to the network 3. For example, the server device 60 stores the fire place information from the first sequencer 12 described above, and transmits the fire place information in response to a request from the terminal device 20. Furthermore, the server device 60 can communicate with the cloud server 5 on the Internet 4, for example. The server device 60 is the same as a known server device in hardware.

  The fire detector 70 detects the occurrence of a fire. The fire detector 70 transmits a fire signal when a fire is detected. A fire signal from the fire detector 70 is received by the fire receiver 11. A plurality of fire detectors 70 are installed in the building 2. When the building 2 is a multi-storey building, a predetermined number of fire detectors 70 are installed on each floor. As shown in FIG. 1, it is assumed that the building 2 is a three-story building having three rooms on each floor. In this case, the fire detector 70 is installed in each room on each floor, for example. The fire detector 70 may be installed in a place of the building 2 different from the room. For example, the fire detector 70 is installed in a place such as a passage. In addition, as a place of the building 2 where the fire detector 70 is installed, a place adjacent to the building 2 is exemplified. As the fire detector 70, a known fire detector is employed. Therefore, the other description regarding the fire detector 70 will be omitted as appropriate.

  The alarm device 80 includes an alarm output machine 81 and a second sequencer 82. In the alarm device 80, the alarm output machine 81 and the second sequencer 82 are communicably connected. For example, the alarm output machine 81 and the second sequencer 82 are wiredly connected by a predetermined communication cable. However, the alarm output machine 81 and the second sequencer 82 may be connected by wireless connection. The alarm output machine 81 is a device that sounds an alarm sound. Examples of the alarm output machine 81 include emergency broadcast equipment and district sound equipment (emergency bell). When the alarm output machine 81 is an emergency broadcasting facility, the alarm sound is an audio alarm sound and is output from a speaker installed in the building 2. In FIG. 1, illustration of the speaker is omitted. When the warning output device 81 is a district acoustic device, the warning sound is a ringing sound (bell sound) output by the district acoustic device. In the fire receiving device 10, when a fire signal is received by the fire receiver 11, a ringing instruction is transmitted from the fire receiver 11 to the alarm output device 81. The alarm output machine 81 outputs an alarm sound in the building 2 when a ringing instruction is received.

  The second sequencer 82 includes, for example, a CPU, a ROM (flash memory), a RAM, and a communication unit. These units are the same as those described above included in the first sequencer 12. In FIG. 1, illustration of each part with which the 2nd sequencer 82 is provided is abbreviate | omitted. The alarm device 80 can communicate with the server device 60 via the communication unit of the second sequencer 82. In the alarm device 80, the stop instruction is received by the communication unit of the second sequencer 82. The stop instruction is an instruction to stop the alarm sound output from the alarm output machine 81. The stop instruction is transmitted from the terminal device 20 to the second sequencer 82 via the server device 60. In the alarm device 80, the second sequencer 82 transmits a stop instruction to the alarm output device 81 when the stop instruction is received by the communication unit. The fire receiver 11 can also transmit a stop signal to the alarm output device 81. The alarm output machine 81 stops the alarm sound being output when the stop signal is received. As the alarm output machine 81, a well-known emergency broadcasting facility or district sound device is used. The second sequencer 82 is the same as a known sequencer in terms of hardware, and can be configured using a known sequencer. Therefore, the other description regarding the alarm output machine 81 and the second sequencer 82 is omitted as appropriate.

  The fire reporting device 90 includes a fire reporting machine 91 and a third sequencer 92. In the fire reporting device 90, the fire reporting machine 91 and the third sequencer 92 are connected to be communicable. For example, the fire alarm device 91 and the third sequencer 92 are wired by a predetermined communication cable. However, the connection between the fire alarm device 91 and the third sequencer 92 may be a wireless connection. The fire reporting device 91 is connected to the fire engine 7 having jurisdiction over the location of the building 2 through the public line 6. The fire notifier 91 makes an emergency call (call 119) to the fire engine 7 and automatically connects to the fire engine 7 to automatically generate the fire and predetermined information related to the building 2 (for example, the name and address of the building 2). Is a device that outputs a sound.

  The third sequencer 92 includes, for example, a CPU, a ROM (flash memory), a RAM, and a communication unit. These units are the same as those described above included in the first sequencer 12. In FIG. 1, illustration of each part with which the 3rd sequencer 92 is provided is abbreviate | omitted. The fire reporting device 90 can communicate with the server device 60 via the communication unit of the third sequencer 92. In the fire notification device 90, the notification instruction is received by the communication unit of the third sequencer 92. The notification instruction is an instruction for causing the fire notification device 91 to execute an emergency notification. The notification instruction is transmitted from the terminal device 20 to the third sequencer 92 via the server device 60. In the fire reporting device 90, the third sequencer 92 transmits a reporting instruction to the fire reporting device 91 when the reporting instruction is received by the communication unit. When the notification instruction is received, the fire reporting device 91 makes an emergency call to the fire engine 7 and, after connecting to the fire engine 7, automatically outputs a predetermined information related to the occurrence of the fire and the building 2. As the fire alarm 91, a known fire alarm is used. The third sequencer 92 is the same as a known sequencer in hardware, and can be configured using a known sequencer. Therefore, the other description regarding the fire alarm 91 and the third sequencer 92 will be omitted as appropriate. The first sequencer 12, the second sequencer 82, and the third sequencer 92 may be the same sequencer in hardware.

<Terminal device>
The terminal device 20 will be described with reference to FIG. The terminal device 20 includes a CPU 21, a ROM 22, a RAM 23, a display unit 24, an operation unit 25, a sound output unit 26, and a communication unit 27. CPU21 performs arithmetic processing. The CPU 21 constitutes a control unit that controls the terminal device 20. The ROM 22 stores various processing programs executed by the CPU 21. For example, the ROM 22 stores a program for main processing (see FIGS. 2 to 4) described later. The ROM 22 stores a plurality of screen data respectively corresponding to each screen to be described later displayed on the display unit 24. Further, the ROM 22 stores floor map data corresponding to the floor map 41 of the building 2 (see the lower part of FIG. 5 described later). The floor map data is, for example, data divided for each floor. That is, when the building 2 is a three-story building (see FIG. 1), the ROM 22 stores floor map data for the first floor, floor map data for the second floor, and floor map data for the third floor. Other description regarding the floor map data will be described later. In the embodiment, the ROM 22 includes a flash memory. The RAM 23 is a storage area used when the CPU 21 executes various programs. The RAM 23 stores predetermined data used in the process during the execution of the process. In the terminal device 20, various processes are executed by the CPU 21 executing a program of the main process stored in the ROM 22. Accordingly, various processing units are configured.

  The display unit 24 displays various screens including predetermined information. As the display unit 24, a liquid crystal display or an organic EL display is exemplified. The operation unit 25 receives an input to the terminal device 20. Examples of the operation unit 25 include a touch pad, a keyboard, and a mouse. In the embodiment in which the terminal device 20 is a tablet terminal, the operation unit 25 is a touch pad. The display unit 24 and the operation unit 25 are integrated to form a touch panel. In the touch panel, the operation unit 25 using a touch pad outputs a two-dimensional coordinate position (X coordinate value and Y coordinate value) indicating a position where a user's finger of the terminal device 20 or a touch pen held by the user touches. The CPU 21 acquires the coordinate position output from the operation unit 25. Such a technique is a known technique employed in a known tablet terminal or the like. Therefore, the other description regarding this is abbreviate | omitted. In the embodiment, the user of the terminal device 20 is referred to as a “security guard”. The sound output unit 26 outputs a predetermined sound. The sound output unit 26 includes a connection unit with headphones or earphones, and a speaker.

  The communication unit 27 connects the terminal device 20 to the network 3 and performs communication via the network 3. In the embodiment in which the terminal device 20 is wirelessly connected to the network 3, the communication unit 27 corresponds to wireless LAN communication. In the terminal device 20, various types of data are transmitted / received to / from the server device 60 via the communication unit 27. The terminal device 20 is different from a known terminal device in that a main processing program is stored in the ROM 22. However, the terminal device 20 is the same as a known tablet terminal in hardware. Therefore, the terminal device 20 includes a configuration included in a known tablet terminal in addition to the above-described units. The same applies to the case where the terminal device 20 is an information processing device having a communication function different from that of the tablet terminal.

<Main processing>
The main process executed by the terminal device 20 will be described with reference to FIGS. The description of the main processing is based on the following state. That is, the fire detectors 70 that have detected a fire are the fire detector 70 installed in the second floor E room and the fire detector 70 installed in the third floor H room. The fire receiver 11 is of a type that can individually identify the place where the fire was detected (Room E, Room 2 and Room H, 3rd floor). In the embodiment, a place where a fire is detected is referred to as a “fire detection place”. Information indicating a fire detection location is referred to as “fire location information”. In the fire receiver 10, the fire receiver 11 receives a fire signal from the fire detector 70 in the second floor E room, and receives a fire signal from the fire detector 70 in the third floor H room. In the fire receiving device 10, the second floor E room and the third floor H room as fire place information are transmitted from the fire receiver 11 to the first sequencer 12, and the first sequencer 12 is in the second floor E room and the third floor H room. Receive. In the first sequencer 12, the CPU 13 transmits the received 2nd floor E room and 3rd floor H room. Accordingly, the second floor room E and the third floor room H are transmitted from the communication unit 14 to the server device 60. The server device 60 receives the second floor E room and the third floor H room. In the server device 60, the second floor room E and the third floor room H are stored in a state associated with the identification numbers (see FIG. 1).

  CPU21 which started the main process transmits a transmission request (S11). The transmission request is an instruction for requesting transmission of fire place information stored in the server device 60. The CPU 21 outputs a transmission request for a transmission request to the communication unit 27. Along with this, a transmission request is transmitted from the communication unit 27 to the server device 60. The server device 60 receives the transmission request. When the fire place information is stored, the server device 60 transmits the fire place information. When the fire place information is not stored, the server device 60 does not transmit a response to the transmission request. However, when the fire place information is not stored, the server device 60 may transmit a response indicating that the fire place information is not stored. In the embodiment, the second floor E room (identification number: 1) and the third floor H room (identification number: 2) are stored in the server device 60 as fire place information. Accordingly, the server device 60 transmits the fire place information “2nd floor E room” and “3rd floor H room”. At this time, an identification number is associated with the fire place information. The identification number is a serial number for identifying each fire place information. In FIG. 1, the identification number is “No.”.

  After executing S11, the CPU 21 determines whether or not fire place information has been acquired (S13). In the terminal device 20, the fire place information transmitted from the server device 60 is received by the communication unit 27. The CPU 21 acquires fire place information via the communication unit 27. After performing S11, when fire place information is not acquired via the communication part 27 within the predetermined period (S13: No), CPU21 returns a process to S11 and performs S11 again. That is, when the fire place information is not acquired (S13: No), the terminal device 20 repeatedly transmits a transmission request at predetermined intervals. When the fire place information is acquired (S13: Yes), the CPU 21 stores the acquired fire place information in the RAM 23 (S15). At this time, identification information transmitted in association with the fire place information is associated with the fire place information. That is, in the terminal device 20 as well as the server device 60, the identification number “1” and the fire place information “second floor E room” are stored in the RAM 23 in association with each other, and the identification number “2” and the fire place information “third floor H” are stored. “Room” is stored in association. The storage location of the fire place information may be the ROM 22.

  Next, the CPU 21 outputs an alarm sound (S17). The CPU 21 reproduces sound data corresponding to the alarm sound. Along with this, an alarm sound is output from the sound output unit 26. Subsequently, the CPU 21 displays a fire information screen (S19). The CPU 21 specifies one of the fire place information stored in the RAM 23. For example, in S19 executed first after starting the main process, the fire place information “2nd floor E room” having the identification number “1” of the fire place information stored in the RAM 23 is the minimum value. Identified. CPU21 produces | generates the fire information screen containing the identified fire place information. The fire information screen is generated using screen data corresponding to this screen stored in the ROM 22 and the specified fire place information. Subsequently, the CPU 21 outputs a display command for the generated fire information screen to the display unit 24. Accordingly, a fire information screen including fire place information is displayed on the display unit 24 (see the upper part of FIG. 5). The fire information screen shown in the upper part of FIG. 5 is a fire information screen corresponding to the case where the fire place information “second floor room E” associated with the identification number “1” is specified as the fire place information. On the fire information screen shown in the upper part of FIG. 5, the fire place information is displayed separately for the floor number and the room name.

  The fire information screen includes fire location information (floor and room name), fire detection number information, previous button 31, next button 32, map display button 33, emergency call button 34, and misinformation registration button 35. A mute button 36 and an end button 37 are included. The fire detection number information is information corresponding to the total number of fire place information stored in the RAM 23. In the embodiment, the number of fire place information that is not displayed as fire place information (fire detection number information = total number of fire place information-1) is displayed. For example, when the fire place information stored in the RAM 23 is the second floor E room (identification number: 1) and the third floor H room (identification number: 2), the fire detection number information is the total number of fire place information “2 cases” ”Is the“ other one ”subtracting the displayed fire place information“ 2nd floor room E ”. The fire detection number information may be the total number of fire place information.

  The front button 31 is operation information (operation button) associated with a switching instruction for switching the displayed fire place information to the fire place information having an identification number one smaller than the identification number of the fire place information. When the displayed fire place information is the fire place information associated with the minimum identification number, the front button 31 may be hidden or disabled (for example, grayed out). The next button 32 is operation information associated with a switching instruction for switching the displayed fire place information to the fire place information having an identification number one larger than the identification number of the fire place information. When the displayed fire place information is the fire place information associated with the largest identification number, the next button 32 may be in a non-displayed or inoperable state (for example, grayed out state).

  The map display button 33 is operation information associated with a floor map instruction. The floor map instruction is an instruction to display a floor map screen including a floor map 41 described later. The emergency call button 34 is operation information associated with the notification instruction. The misinformation registration button 35 is operation information associated with a stop instruction. The mute button 36 is operation information associated with a mute instruction. The mute instruction is an instruction to stop the output of the alarm sound from the sound output unit 26. The end button 37 is operation information associated with the end instruction. The end instruction is an instruction to end the main process.

  After executing S19, the CPU 21 determines whether or not an end instruction has been acquired (S21). The end instruction is input when the end button 37 is pressed. When pressing of the end button 37 is received by the operation unit 25, the CPU 21 acquires an end instruction. When the end instruction is acquired (S21: Yes), the CPU 21 ends the main process. When the end instruction has not been acquired (S21: No), the CPU 21 determines whether or not a switching instruction has been acquired (S23). The switching instruction is input by pressing the previous button 31 or the next button 32. When the pressing of the front button 31 is accepted by the operation unit 25, the CPU 21 issues a switching instruction to switch the displayed fire place information to the fire place information having an identification number one smaller than the identification number of the fire place information. get. When the pressing of the next button 32 is accepted by the operation unit 25, the CPU 21 issues a switching instruction to switch the displayed fire place information to the fire place information having an identification number one larger than the identification number of the fire place information. get.

  When the switching instruction is acquired (S23: Yes), the CPU 21 returns the process to S19, and switches the displayed fire information screen to the fire information screen including the fire place information corresponding to the acquired switching instruction. The operation unit 25 accepts that the next button 32 has been pressed while the displayed fire information screen is shown in the upper part of FIG. 5, and the CPU 21 has acquired a switching instruction to switch to the fire location information with one larger identification number And In this case, the CPU 21 specifies the fire place information “3rd floor H room” associated with the identification number “2” stored in the RAM 23 and generates a fire information screen including the fire place information “3rd floor H room”. . Subsequently, the CPU 21 outputs a display command for the generated fire information screen to the display unit 24. Accordingly, the fire information screen displayed on the display unit 24 is switched from the state shown in the upper part of FIG. 5 to a fire information screen in which the floor number is “3rd floor” and the room name is “Room H”. When the switching instruction has not been acquired (S23: No), the CPU 21 shifts the process to S25 of FIG.

  In S25 of FIG. 3, the CPU 21 determines whether or not a floor map instruction has been acquired. The floor map instruction is input when the map display button 33 is pressed. When the depression of the map display button 33 is received by the operation unit 25, the CPU 21 acquires a floor map instruction. When the floor map instruction has not been acquired (S25: No), the CPU 21 proceeds to S41 in FIG. When the floor map instruction is acquired (S25: Yes), the CPU 21 displays a floor map screen (S27). The CPU 21 acquires screen data and floor map data corresponding to the floor map screen from the ROM 22. The acquired floor map data is floor map data including the fire detection location indicated by the fire location information included in the displayed fire information screen. CPU21 produces | generates the floor map screen containing the floor map 41 corresponding to the fire place information contained in the fire information screen being displayed, and the acquired floor map data. The floor map screen is generated using the acquired screen data and floor map data and the fire place information included in the displayed fire information screen. Subsequently, the CPU 21 outputs a display command for the generated floor map screen to the display unit 24. Accordingly, the floor map screen is displayed on the display unit 24 (see the lower part of FIG. 5). The floor map screen displayed in this way includes the floor map 41 of the building 2 including the fire detection location indicated by the fire location information included in the fire information screen displayed immediately before the floor map screen is displayed (FIG. 5). reference).

  In the embodiment, the floor map 41 of the building 2 including the fire detection place is the entire floor on the same floor as the fire detection place. However, the floor map 41 of the building 2 including the fire detection location may be a partial range including the fire detection location in the entire floor on the same floor as the fire detection location. Furthermore, the floor map 41 of the building 2 including the fire detection location may be a floor map of the entire building 2. The range in the building 2 displayed as the floor map 41 is appropriately determined in consideration of various conditions. Each place in the building 2 included in the floor map 41 in the floor map screen is associated with place information indicating the place. Based on the lower part of FIG. 5, the location information “2nd floor D room” is associated with the display area where the second floor D room is displayed, and the location information “ The location information “second floor F room” is associated with the display area in which “second floor E room” is associated and the second floor F room is displayed. The display area of each room is specified by, for example, each two-dimensional coordinate position (X coordinate value and Y coordinate value). The place in the building 2 to which the place information is associated may be a display area other than the room.

  In the floor map screen, the floor map 41 includes facility information 42 indicating disaster prevention facilities installed in the building 2. Examples of disaster prevention equipment include fire doors, emergency stairs and digestive organs (see the lower part of FIG. 5). In addition, although illustration is abbreviate | omitted in the lower stage of FIG. 5, a fire hydrant is illustrated as disaster prevention equipment. In the floor map screen, the floor map 41 includes route information 43 indicating an evacuation route from a fire detection place to a safe place. The route information 43 is indicated by an arrow (see the lower part of FIG. 5). However, as long as the route information 43 is information that clearly indicates the evacuation route, the route information 43 may be in a mode (for example, a character) different from the arrow. On the floor map screen, the facility information 42 and / or the route information 43 may be color-coded and / or blinked with other portions. Although not shown in the lower part of FIG. 5, the floor map screen may further display a procedure for handling work to be performed by the guard. The guard can understand the type and position of the disaster prevention facility based on the facility information 42, understand the evacuation route based on the route information 43, and can recognize the corresponding procedure of work to be performed. The security guard can then perform initial fire fighting activities and / or evacuation guidance activities. The floor map screen includes floor information 41, facility information 42, route information 43, floor information 44, alert information 45, and a return button 46. The floor information 44 is information indicating the position of the floor map 41 to be displayed in the building 2 and indicates the floor. The alert information 45 is information for distinguishing the fire detection location from other locations. In the embodiment, the alert information 45 is a frame line. In the floor map screen shown in FIG. 5, the letter “E room” indicating the second floor E room as a fire detection place is surrounded by a frame line as the alert information 45 and is distinguished from other places. The alert information 45 and / or characters indicating the fire detection location (refer to “Room E” in the lower part of FIG. 5) may also be color-coded and / or blinked with other portions. The return button 46 is operation information associated with the first return instruction. The first return instruction is an instruction to display the fire information screen displayed immediately before the floor map screen is displayed.

  After executing S27, the CPU 21 determines whether or not a first return instruction has been acquired (S29). The first return instruction is input by pressing the return button 46. When pressing of the return button 46 is received by the operation unit 25, the CPU 21 acquires a first return instruction. When the first return instruction is acquired (S29: Yes), the CPU 21 returns the process to S19 in FIG. In S19, the CPU 21 displays the fire information screen displayed immediately before the floor map screen is displayed. When the first return instruction has not been acquired (S29: No), the CPU 21 determines whether an area instruction has been acquired (S31). The area instruction is an instruction for designating a predetermined place in the floor map 41 in a state where the floor map screen is displayed. For example, in the state where the floor map screen shown in the lower part of FIG. Coordinate position is acquired as an area instruction.

  When the area instruction has not been acquired (S31: No), the CPU 21 returns the process to S29 and executes S29 again. When the area instruction is acquired (S31: Yes), the CPU 21 displays a disaster information screen (S33). The CPU 21 specifies location information indicating a place in the building 2 indicated by the area instruction from the coordinate position acquired as the area instruction and the coordinate position of the display area of each place in the building 2 included in the floor map 41. For example, in the state where the floor map screen shown in the lower part of FIG. 5 is displayed, when the operation unit 25 receives a press into the area of the room D in the floor map 41, the CPU 21 has been acquired as an area instruction. From the coordinate position and the coordinate position of the display area of each place in the building 2 included in the floor map 41, the place information “second floor D room” is specified. In the embodiment, the location information specified with the acquisition of the area instruction is referred to as “designated location information”. The CPU 21 generates a disaster information screen including the specified designated place information. The disaster information screen is generated using screen data corresponding to this screen stored in the ROM 22 and designated location information. The CPU 21 outputs a display instruction for the disaster information screen to the display unit 24. Along with this, the disaster information screen is displayed on the display unit 24 (see FIG. 6).

  The disaster information screen includes a numeric keypad 51, an input box 52, a confirmation button 53, and a return button 54 in addition to the designated location information. On the disaster information screen, input of the number of victims in the place in the building 2 indicated by the designated place information is accepted. The numeric keypad 51 is used when inputting the number of victims. The guard presses the numeric keypad 51 and inputs the number of victims. In the input box 52, when the operation unit 25 accepts pressing of a predetermined numeric key included in the numeric keypad 51, the accepted numeric value is displayed. The confirmation button 53 is operation information associated with the confirmation instruction. The confirmation instruction is an instruction to use the numerical value displayed in the input box 52 as the confirmation value. When the numerical value is not displayed in the input box 52, the confirmation button 53 may be hidden or inoperable (for example, grayed out). The return button 54 is operation information associated with the second return instruction. The second return instruction is an instruction to display the floor map screen that was displayed immediately before the display of the disaster information screen.

  After executing S33, the CPU 21 determines whether or not a second return instruction has been acquired (S35). The second return instruction is input by pressing the return button 54. When pressing of the return button 54 is accepted by the operation unit 25, the CPU 21 acquires a second return instruction. When the second return instruction is acquired (S35: Yes), the CPU 21 returns the process to S27. In S27, the CPU 21 displays the floor map screen displayed immediately before. When the second return instruction has not been acquired (S35: No), the CPU 21 determines whether a confirmation instruction has been acquired (S37). The guard presses the numeric keypad 51 and inputs the number of victims. When pressing of a predetermined numeric key included in the numeric keypad 51 is received by the operation unit 25, the CPU 21 acquires a numerical value output from the operating unit 25 and causes the input box 52 to display the acquired numerical value. Thereafter, the guard presses the confirmation button 53. When the pressing of the confirmation button 53 is accepted by the operation unit 25, the CPU 21 acquires a confirmation instruction. At this time, the CPU 21 acquires the numerical value displayed in the input box 52 as the disaster victim value, and further acquires the specified location information included in the disaster information screen being displayed.

  When the confirmation instruction has not been acquired (S37: No), the CPU 21 returns the process to S35 and executes S35 again. When the confirmation instruction is acquired (S37: Yes), the CPU 21 transmits rescue information (S39). The rescue information includes a disaster victim value and designated location information acquired together with the confirmation instruction. The transmission destination of the rescue information is the server device 60. The CPU 21 outputs a rescue information transmission command to the communication unit 27. Along with this, rescue information is transmitted from the communication unit 27 to the server device 60. In the server device 60, the rescue information is received. In the server device 60, the received rescue information is stored. That is, in the server device 60, the victim value and the designated location information included in the received rescue information are stored in association with each other.

  After executing S39, the CPU 21 returns the process to S19 of FIG. Thereafter, the CPU 21 executes the processes after S19 again. In this case, the fire information screen displayed in S19 is a screen including the same fire place information as the fire information screen displayed in S19 executed last time. However, when a plurality of fire place information is stored in the RAM 23, in S19 after execution of S39, a fire information screen including fire place information different from the fire information screen displayed in S19 executed last time is displayed. You may do it. Which fire information screen is displayed is appropriately determined in consideration of various circumstances.

  In S41 of FIG. 4, the CPU 21 determines whether or not a notification instruction has been acquired. The notification instruction is input by pressing the emergency notification button 34 in the fire information screen (see the upper part of FIG. 5). For example, the guard moves to or near the fire detection location indicated by the fire location information in accordance with the fire location information included in the fire information screen. The guard presses the emergency call button 34 when the occurrence of the fire can be confirmed. When the pressing of the emergency notification button 34 is accepted by the operation unit 25, the CPU 21 acquires a notification instruction. When the report instruction is acquired (S41: Yes), the CPU 21 transmits the report instruction (S43). The transmission destination of the notification instruction is the server device 60. The CPU 21 outputs a notification instruction transmission command to the communication unit 27. Along with this, a notification instruction is transmitted from the communication unit 27 to the server device 60. The server device 60 receives the notification instruction. The server device 60 transmits the received notification instruction to the third sequencer 92. Thereafter, in the fire notification device 90, as described above, an emergency notification to the fire engine 7 is executed. After executing S43, the CPU 21 ends the main process.

  When the notification instruction has not been acquired (S41: No), the CPU 21 determines whether or not a stop instruction has been acquired (S45). The stop instruction is input by pressing the misinformation registration button 35. For example, the guard moves to or near the fire detection location indicated by the fire location information in accordance with the fire location information included in the fire information screen. If the security guard cannot confirm the occurrence of the fire, the guard presses the misinformation registration button 35. When the pressing of the misinformation registration button 35 is accepted by the operation unit 25, the CPU 21 acquires a stop instruction. When the stop instruction has not been acquired (S45: No), the CPU 21 shifts the process to S53. When the stop instruction is acquired (S45: Yes), the CPU 21 has acquired the fire location information stored in the RAM 23 in association with the fire location information that matches the fire location information included in the displayed fire information screen. Information is stored (S47).

  Next, the CPU 21 determines whether or not the acquired information is stored in association with all the fire place information stored in the RAM 23 (S49). When the acquired information is not stored in association with all the fire place information stored in the RAM 23 (S49: No), the CPU 21 returns the process to S19 in FIG. Thereafter, the CPU 21 executes the processes after S19 again. In this case, the fire information screen displayed in S19 may be a fire information screen including fire place information that is not associated with information already acquired in the RAM 23. It is confirmed that no fire has occurred at the fire detection location indicated by the fire location information associated with the acquired information, and such a fire detection location is subject to confirmation again in an emergency situation. This can be prevented.

  When the acquired information is stored in association with all the fire place information stored in the RAM 23 (S49: Yes), the CPU 21 transmits a stop instruction (S51). The transmission destination is the server device 60. The CPU 21 outputs a stop instruction transmission command to the communication unit 27. Along with this, a stop instruction is transmitted from the communication unit 27 to the server device 60. The server device 60 receives a stop instruction. The server device 60 transmits the received stop instruction to the second sequencer 82. Thereafter, in the alarm device 80, as described above, the alarm sound being output by the alarm output device 81 is stopped. After executing S51, the CPU 21 ends the main process. When the number of fire place information stored in the RAM 23 is one, S49 is always affirmed (S49: Yes).

  In S53, the CPU 21 determines whether a mute instruction has been acquired. The mute instruction is input by pressing the mute button 36. The guard presses the mute button 36 when stopping the output of the alarm sound from the sound output unit 26. When the depression of the mute button 36 is accepted by the operation unit 25, the CPU 21 acquires a mute instruction. When the mute instruction is acquired (S53: Yes), the CPU 21 stops the reproduction of the sound data corresponding to the alarm sound (S55). Accordingly, the output of the alarm sound from the sound output unit 26 is stopped. After executing S55, the CPU 21 returns the process to S21 of FIG. 2, and executes the processes after S21 again.

<Effect of embodiment>
According to the embodiment, the following effects can be obtained.

  (1) When the fire place information is acquired, the terminal device 20 outputs an alarm sound and displays a fire information screen including the fire place information (S13: Yes, S17, S19 in FIG. 2 and the upper part of FIG. 5). reference). The acquired fire place information is stored in the RAM 23 (see S15 in FIG. 2). In the terminal device 20, when the map display button 33 is pressed by the guard while the fire information screen is displayed, the floor map instruction is acquired and the floor map screen is displayed (S25 in FIG. 3: Yes, (See S27 and the lower part of FIG. 5). The floor map screen includes a floor map 41 including a fire detection location indicated by the fire location information included in the fire information screen. Therefore, the alarm sound from the sound output unit 26 can notify the security guard that a fire has occurred or that a fire may have occurred. The security guard can recognize the fire detection location from the fire location information on the fire information screen. The security guard can display the floor map screen while recognizing the fire detection location. The security guard can consider the response to the fire based on the floor map 41 in the floor map screen. In the fire information screen and the floor map screen (see FIG. 5), the background color of the screen may be, for example, a color excellent in visibility even in smoke. For example, in each screen described above, the background color is pink.

  (2) In the terminal device 20, when a predetermined location in the building 2 included in the floor map 41 is pressed by a security guard while the floor map screen is displayed, an area instruction corresponding to the pressed location is issued. The designated location information is acquired, and the disaster information screen including the designated location information is displayed (see S31 in FIG. 3: Yes, S33 and FIG. 6). In the terminal device 20, when the confirmation button 53 is pressed by the guard while the disaster information screen is displayed, the victim value and the specified location information that are input according to the display of the disaster information screen are acquired together with the confirmation instruction. Then, rescue information including the victim value and designated location information is transmitted to the server device 60 (see S37 in FIG. 3: Yes, S39). In the server device 60, the victim value and the designated location information are stored in association with each other. Therefore, by accessing the server device 60, a plurality of persons can share the number of victims and the location where the victims are located. Smooth rescue operations are possible. In the disaster information screen (see FIG. 6), the background color of the screen may be, for example, a color having excellent visibility (for example, pink) in smoke as in the fire information screen and the floor map screen.

  (3) In the terminal device 20, when the emergency notification button 34 is pressed by the security guard while the fire information screen is displayed, the notification instruction is acquired and the notification instruction is transmitted to the fire notification device 90 ( (See S41 in FIG. 4: Yes, S43). In the fire reporting device 90, the third sequencer 92 receives a reporting instruction, and an emergency report from the fire reporting device 91 to the fire engine 7 is executed. Therefore, an emergency call can be executed from the terminal device 20. Prompt emergency call is possible.

  (4) In the terminal device 20, when the misinformation registration button 35 is pressed by a security guard while the fire information screen is displayed, a stop instruction is acquired, and the fire place information stored in the RAM 23 is being displayed. The acquired information is stored in association with the fire place information that matches the fire place information included in the fire information screen (see S45 in FIG. 4: Yes, S47). And when acquired information is linked | related and memorize | stored with respect to all the fire place information memorize | stored in RAM23, a stop instruction | indication is transmitted to the alarm device 80 (refer S49 of FIG. 4: Yes, S51). In the alarm device 80, the stop instruction is received by the second sequencer 82, and the alarm sound being output is stopped by the alarm output device 81. Therefore, it is possible to avoid a state in which an alarm sound continues to sound. For example, when the fire detector 70 malfunctions, the alarm sound can be easily stopped.

<Modification>
The embodiment can also be performed as follows. Some configurations of the modifications shown below can be appropriately combined and employed. Hereinafter, points different from the above will be described, and description of similar points will be omitted as appropriate.

  (1) In the above, the notification instruction is transmitted from the terminal device 20 to the third sequencer 92 of the fire notification device 90 via the server device 60 (see S43 in FIG. 4). The terminal device 20 and the third sequencer 92 may be directly communicated with each other via the network 3. In this case, the transmission destination of the notification instruction is the third sequencer 92 in S43 of FIG. The notification instruction is transmitted from the communication unit 27 to the third sequencer 92. The stop instruction is transmitted from the terminal device 20 to the second sequencer 82 via the server device 60 (see S51 in FIG. 4). The terminal device 20 and the second sequencer 82 may be directly communicated via the network 3. In this case, the transmission destination of the stop instruction is the second sequencer 82 in S51 of FIG. The stop instruction is transmitted from the communication unit 27 to the second sequencer 82.

  (2) In the above, the fire receiving device 10 includes the fire receiver 11 and the first sequencer 12. In the fire receiving device 10, the fire receiver 11 and the first sequencer 12 are connected so as to be communicable. The fire receiving device may be a single device in which the fire receiver and the first sequencer are integrated. In the integrated fire receiving device, when a fire signal from the predetermined fire detector 70 is received, the CPU of the fire receiving device transmits a ringing instruction to the alarm output device 81 of the alarm device 80. In the integrated fire receiving device, when a fire signal from a predetermined fire detector 70 is received, the CPU of the fire receiving device acquires this fire signal, and the fire detector 70 that detects the fire is installed. Fire location information indicating the fire detection location is transmitted from the communication unit of the fire receiving device to the server device 60. Furthermore, the fire receiving device may be a device having a server function equivalent to that of the server device 60. In this case, the server device 60 is omitted, and the fire receiving device functions as the server device 60 described above.

  The alarm device 80 includes an alarm output machine 81 and a second sequencer 82. In the alarm device 80, the alarm output machine 81 and the second sequencer 82 are communicably connected. The alarm device may be a single device in which the alarm output machine and the second sequencer are integrated. In the integrated alarm device, when a stop instruction from the terminal device 20 is received, the CPU of the alarm device acquires the stop instruction via the communication unit of the alarm device, and instructs the configuration corresponding to the alarm output machine to stop. Is output. The fire notification device 90 includes a fire notification device 91 and a third sequencer 92. In the fire reporting device 90, the fire reporting machine 91 and the third sequencer 92 are connected to be communicable. The fire reporting device may be a single device in which the fire reporting machine and the third sequencer are integrated. In the integrated fire notification device, when a notification instruction from the terminal device 20 is received, the CPU of the fire notification device acquires the notification instruction via the communication unit of the fire notification device, and corresponds to a fire notification device. A notification instruction is output.

  (3) In the above, the fire detection location is a predetermined range of the building 2 divided by the unit in which the fire detector 70 is provided, and the fire location information is information indicating the fire detection location according to the aforementioned range. did. For example, the fire detection location and the fire location information when a fire is detected by the fire detector 70 installed in the second floor E room is the second floor E room. That is, the fire detection location is a unit of each room provided with one fire detector 70, and the fire detection location information is a combination of the floor number and the room name of each room. The fire detection location may be set to a predetermined range monitored by a plurality of fire detectors 70. For example, the fire detection place may be divided for each floor number. Fire place information is indicated by the number of floors. In this case, for example, even if a fire is detected by any of the fire detectors 70 installed in the second floor D room, the second floor E room, and the second floor F room, the fire detection place is on the second floor of the building 2. There is fire place information on the second floor. In addition, the fire detection location and the fire location information may be set in a range such as the second floor east side or the second floor west side.

  (4) In the above, the floor map data is stored in the ROM 22 in the terminal device 20. The floor map data may be stored in the server device 60, and the floor map data may be transmitted from the server device 60 to the terminal device 20. The server device 60 transmits the floor map data together with the identification number and the fire place information. The floor map data is data corresponding to the floor map 41 including the fire detection location indicated by the fire location information to be transmitted. In addition, when S25 of the main process (see FIGS. 2 to 4) is affirmed (see S25: Yes in FIG. 3), before executing S27, a floor map data transmission request is transmitted to the server device 60. You may make it acquire floor map data from the server apparatus 60. FIG. In this case, the transmission request includes the fire place information included in the displayed fire information screen. In the server device 60, the floor map data to be transmitted is specified according to the fire place information.

  (5) In the above, when the fire place information is acquired by the terminal device 20 (see S13 in FIG. 2: Yes), an alarm sound is output from the sound output unit 26 (see S17 in FIG. 2). In the terminal device 20, when fire place information is acquired (refer to S13 of FIG. 2: Yes), the light emitting body (not shown) provided in the terminal device 20 is turned on or blinked together with the alarm sound or instead of the alarm sound. You may do it. When the fire place information is acquired by the terminal device 20 (see S13 in FIG. 2: Yes), the fire detection place indicated by the fire place information included in the fire information screen is displayed on the fire information screen displayed in S19 in FIG. You may make it include the floor map 41 containing. In this case, the map display button 33 may be omitted on the fire information screen, and S25 to S29 in FIG. 3 may be omitted in the main process (see FIGS. 2 to 4). In the main process, when S23 in FIG. 2 is negative (see S23: No), the process proceeds to S31 in FIG. If S31 is negative (see S31: No), the process proceeds to S41 of FIG.

  (6) In the above, the number of terminal devices 20 in the fire alarm system 1 is one. The fire alarm system 1 may include a plurality of terminal devices 20. When there are a plurality of guards, each guard operates each terminal device 20. In this case, the main processing (see FIGS. 2 to 4) described above is executed by each of the plurality of terminal devices 20. In connection with S47 of FIG. 4, the terminal device 20 may transmit confirmation information to the server device 60. The confirmation information includes the identification information, the fire place information, and the acquired information stored in association with each other in S47. In the confirmation information, the identification information may be omitted. The server device 60 receives the confirmation information from the terminal device 20, and stores the acquired information in association with the identification information and the fire location information that match the identification information and the fire location information included in the confirmation information. The server device 60 transmits confirmation information to each of the plurality of terminal devices 20. In the terminal device 20, the acquired information is stored in association with the identification information and the fire place information that match the identification information and the fire place information included in the confirmation information. This storage can be omitted in the terminal device 20 that is the transmission source of the confirmation information. You may make it exclude the terminal device 20 of the transmission source of confirmation information from the terminal device 20 used as the transmission destination of confirmation information. According to such a configuration, the identification information, the fire place information, and the acquired information can be synchronized by the plurality of terminal devices 20. The occurrence of a situation in which a plurality of guards confirm the same fire detection location can be suppressed.

  (7) In the above, when the occurrence of a fire is detected by the fire detector 70, the fire place information is stored in the server device 60 (see FIG. 1). Further, the server device 60 receives the rescue information transmitted from the terminal device 20 in S39 of FIG. 3, and stores the disaster victim value and the designated location information. The server device 60 may transmit the above-described information stored in the own device to the cloud server 5 via the Internet 4. The cloud server 5 stores the received information described above. It becomes possible to acquire the above-described information from the cloud server 5 using a communication terminal that can be connected to the Internet 4. From the outside of the building 2, it is possible to confirm the fire occurrence location and rescue information (disaster victim value and designated location information). You may make it access to the above-mentioned each information memorize | stored in the cloud server 5 through predetermined | prescribed authentication. It is also possible to send an e-mail including the above-mentioned information stored in the cloud server 5 with a pre-registered mail address as a destination.

DESCRIPTION OF SYMBOLS 1 Fire alarm system, 2 Building, 3 Network, 4 Internet 5 Cloud server, 6 Public line, 7 Fire engine, 10 Fire receiver 11 Fire receiver, 12 First sequencer, 13 CPU, 14 Communication part 20 Terminal device, 21 CPU, 22 ROM, 23 RAM, 24 display section 25 operation section, 26 sound output section, 27 communication section, 31 previous button 32 next button, 33 map display button, 34 emergency call button 35 false alarm registration button, 36 mute button, 37 End button 41 Floor map, 42 Equipment information, 43 Route information, 44 Floor information 45 Alert information, 46 Back button, 51 Numeric keypad, 52 Input box 53 Confirm button, 54 Return button, 60 Server device, 70 Fire detector 80 Alarm device , 81 Alarm output machine, 82 The sequencer 90 fire warning apparatus, 91 fire notifier, 92 third sequencer

  The present invention relates to a program for causing a control unit that controls a terminal device included in a fire alarm system installed in a building to automatically notify a fire that has occurred in a building to execute a predetermined process, a terminal device, and a fire alarm system. .

  Technologies related to fire alarms have been proposed. For example, Patent Document 1 discloses an equipment management apparatus. In the facility management apparatus, the display control means receives the event detection signal output from the event detection means. The event detection signal indicates that an event such as a fire has occurred. The display control means retrieves the tunnel background image corresponding to the event occurrence position from the tunnel background image storage means and displays it on the display screen of the display means. Further, the display control means superimposes and displays the facilities existing in the displayed tunnel background image on the displayed tunnel background image by a pictorial display. The aforementioned facility is, for example, an evacuation pit. When the operator wants to know the detailed information of the equipment displayed as a picture, the operator selects and designates the picture display using the selection means. The display control means determines the type of equipment requested from the designated picture display. The display control means superimposes and displays the still image representing the appearance of the equipment, the installation position of the kilometer post, and the specifications of the equipment on the tunnel background image in a window manner. As the selection means, a touch panel or a tablet arranged on the display screen of the display means is used. In Patent Document 1, the facility management apparatus is generated in a tower facility having a relatively large-capacity high-rise building, an amusement hall facility such as a movie theater with a large capacity, or an observation room provided at a high position. It is also possible to adopt a configuration corresponding to various accidents including fire.

JP-A-9-154124

  Fire detectors, fire receivers and alarm outputs may be installed in buildings. The fire receiver is installed, for example, in one room (for example, a management room or a guard room) in a building that serves as a security or monitoring base for the building. Examples of the alarm output machine include emergency broadcast equipment and district sound equipment (emergency bell). When a fire detector detects a fire, the fire receiver sounds an alarm output device. A person in the building can know the occurrence of a fire by an alarm sound. The inventor shall further provide a place where a fire has occurred to a security guard or a supervisor who is away from the above-mentioned place serving as a base for security or monitoring of a building in a situation where a fire has occurred or is suspected. Or, a technology that can notify the location where a fire may have occurred was examined.

  An object of the present invention is to provide a program for a terminal device, a terminal device, and a fire alarm system that enable a quick response when a fire has occurred or when a fire may have occurred.

One aspect of the present invention provides a control unit that controls a terminal device included in a fire alarm system installed in the building that automatically notifies of a fire that has occurred in a building, with a fire detector installed in the building. If the occurrence is sensed, a first acquisition processing for acquiring fire location information indicating the fire place the fire detector is installed which senses fire, through the communication unit of the previous SL terminal device, the fire place When the information is acquired, in a state where the floor map of the building including the fire detection location is displayed on the display unit of the terminal device and the floor map is displayed on the display unit, A second acquisition process for acquiring an area instruction for specifying a predetermined place of the building in the floor map via the operation unit of the terminal device, and when the area instruction is acquired, the area instruction is at the predetermined place. Disaster In the second display process for displaying the disaster information corresponding to the identification of the number of people on the display unit, and in the state where the disaster information is displayed on the display unit, the victim value indicating the number of the victims, Rescue information including the third acquisition process acquired via the operation unit and the disaster victim value and the designated location information indicating the predetermined location when the disaster victim value is acquired, the communication unit To the storage device having a server function capable of storing the disaster victim value and the designated location information . According to this program, when the occurrence of a fire is detected by the fire detector, the floor map including the fire detection location can be displayed on the display unit. The user of the terminal device can consider the response to the fire based on the floor map displayed on the display unit. Area instructions can be acquired according to the display of the floor map, and the disaster information can be displayed on the display unit. And according to the display of disaster information, a disaster victim value can be acquired and rescue information can be transmitted to a memory | storage device. Accordingly, by accessing the storage device, a plurality of persons can share the number of victims and the location of the victims. Smooth rescue operations are possible.

The program, the control unit, when said fire location information is acquired, and the fire place information, the third display processing for displaying a map display operation information corresponding to the display of the floor map, to the display unit And a fourth acquisition process for acquiring a floor map instruction for instructing display of the floor map via the operation unit of the terminal device in a state where the map display operation information is displayed on the display unit. The first display process may be executed when the fire place information and the floor map instruction are acquired. According to this configuration, the fire place information and the map display operation information can be displayed on the display unit. A floor map instruction can be acquired in accordance with the display of the map display operation information on the display unit, and the floor map can be displayed. The user of the terminal device can recognize the fire detection location based on the fire location information and display the floor map.

In the third display process, when the fire location information is acquired, an alarm output from an alarm device installed in the building that outputs an alarm sound in response to the occurrence of a fire detected by the fire detector This is a process for further displaying stop operation information corresponding to sound stop on the display unit, and the program is displayed on the display unit with the stop operation information being displayed on the display unit. A fifth acquisition process for acquiring a stop instruction for instructing to stop the alarm sound output from the operation unit, and when the stop instruction is acquired, the stop instruction is transmitted from the communication unit to the alarm device. The second transmission process to be executed may be executed. According to this configuration, a stop instruction can be acquired in accordance with the display of the stop operation information on the display unit, and the stop instruction can be transmitted to the alarm device. Therefore, the alarm sound being output by the alarm device can be stopped from the terminal device. It is possible to avoid a state in which an alarm sound continues to sound. For example, when a fire detector malfunctions, the alarm sound can be easily stopped.

In the third display process, when the fire location information is acquired, emergency notification operation information corresponding to execution of an emergency call from a fire notification device installed in the building to a fire engine having jurisdiction over the location of the building is displayed. The program is further displayed on the display unit, and the program instructs the control unit to execute an emergency call on the fire notification device in a state where the emergency call operation information is displayed on the display unit. A sixth acquisition process for acquiring a notification instruction to be transmitted via the operation unit; and a third transmission process for transmitting the notification instruction from the communication unit to the fire notification device when the notification instruction is acquired. You may make it perform. According to this configuration, it is possible to acquire a notification instruction according to the display of the emergency notification operation information on the display unit, and transmit the notification instruction to the fire notification device. Therefore, the emergency notification from the fire notification device to the fire engine can be executed from the terminal device. Prompt emergency call is possible.

Route said first display processing, which shows the equipment information indicating the disaster prevention facilities including at least one of escape the digestive and fire hydrant and the installed fire door to the building, the escape routes from the fire place The floor map including one or both of the information and the information may be displayed on the display unit. According to this configuration, a floor map including facility information and / or an evacuation route can be displayed. The user of the terminal device can understand the type and position of the disaster prevention facility and / or the evacuation route based on the floor map displayed on the display unit.

Another aspect of the present invention is a terminal apparatus included in the fire alarm system installed in the building to notify the fire occurring in a building automatically, communicate unit, fire detector installed in the building When the occurrence of a fire is detected at the first acquisition processing unit for acquiring the fire location information indicating the fire detection location where the fire detector that has detected the fire is installed, via the communication unit, a display unit, When the fire location information is acquired, a first display processing unit that causes the display unit to display a floor map of the building including the fire detection location, an operation unit, and the floor map are displayed on the display unit. A second acquisition processing unit that acquires, via the operation unit, an area instruction that specifies a predetermined location of the building in the floor map, and when the area instruction is acquired, the predetermined instruction Disaster victims The second display processing unit that displays the disaster information corresponding to the identification of the number of people on the display unit, and in the state where the disaster information is displayed on the display unit, the victim value indicating the number of the victims, A third acquisition processing unit that is acquired via the operation unit, and, when the disaster victim value is acquired, rescue information including the disaster victim value and designated location information indicating the predetermined location, the communication A first transmission processing unit that causes a storage device having a server function capable of storing the disaster victim value and the designated location information from a unit .

Still another aspect of the present invention is a fire alarm system installed in the building that includes a communicable fire receiver and a terminal device, and automatically notifies of a fire that has occurred in a building, wherein the fire receiver is , when the occurrence of a fire in the installed fire detectors in the building is sensed, it includes a first communication unit that sends fire location information indicating fire sensing and the fire detector is installed the fire place and The terminal device includes a second communication unit, a first acquisition processing unit that acquires the fire location information via the second communication unit, a display unit, and the fire location information, In a state where the floor map of the building including the fire detection location is displayed on the display unit, a first display processing unit, an operation unit, and the floor map are displayed on the display unit, the floor map Specify a predetermined place in the building A second acquisition processing unit that acquires a rear instruction via the operation unit; and when the area instruction is acquired, the display unit displays disaster information corresponding to the identification of the number of disaster victims in the predetermined location. A second display processing unit for displaying on the display unit, and a third acquisition processing unit for acquiring a disaster victim value indicating the number of the disaster victims via the operation unit in a state where the disaster information is displayed on the display unit. When the disaster victim value is acquired, rescue information including the disaster victim value and designated location information indicating the predetermined location is sent from the second communication unit to the disaster victim value and the designated location information. And a first transmission processing unit that transmits the data to a storage device having a server function capable of storing .

According to this terminal device and this fire alarm system, when the occurrence of a fire is detected by a fire detector, a floor map including a fire detection location can be displayed on the display unit. The user of the terminal device can consider the response to the fire based on the floor map displayed on the display unit. Area instructions can be acquired according to the display of the floor map, and the disaster information can be displayed on the display unit. And according to the display of disaster information, a disaster victim value can be acquired and rescue information can be transmitted to a memory | storage device. Accordingly, by accessing the storage device, a plurality of persons can share the number of victims and the location of the victims. Smooth rescue operations are possible. This terminal device or the terminal device in this fire alarm system can also be specified as a terminal device having a configuration corresponding to the predetermined processing of each program described above. In this case, the terminal device or the fire alarm system has the same operation as the corresponding program among the above programs.

  ADVANTAGE OF THE INVENTION According to this invention, the program for terminal devices, a terminal device, and a fire alerting | reporting system which can respond promptly when a fire has occurred or a fire may have occurred can be obtained.

It is a figure which shows an example of schematic structure of the building in which the fire alarm system and the fire alarm system were installed. It is a flowchart of the 1st part of the main process performed with a terminal device. It is a flowchart of the 2nd part of a main process. It is a flowchart of the 3rd part of a main process. It is a figure which shows an example of the screen displayed on a terminal device by the main process. The top row shows an example of the fire information screen. The lower part shows an example of the floor map screen displayed when the map display button is pressed while the fire information screen shown in the upper part is displayed. It is a figure which shows an example of the damage information screen displayed on a terminal device by the main process. The disaster information screen shown in FIG. 6 corresponds to a case where a predetermined position of the second floor room D is pressed while the floor map screen shown in the lower part of FIG. 5 is displayed.

  Embodiments for carrying out the present invention will be described with reference to the drawings. The present invention is not limited to the configurations described below, and various configurations can be employed in the same technical idea. For example, some of the configurations shown below may be omitted or replaced with other configurations. Other configurations may be included.

<Overall configuration of fire alarm system and building>
The overall configuration of the fire alarm system 1 and the building 2 will be described with reference to FIG. The fire alarm system 1 is installed in a building 2 together with a fire detector 70, an alarm device 80, and a fire alarm device 90. The fire alarm system 1 constructs a disaster prevention system for the building 2 together with the fire detector 70, the alarm device 80, and the fire alarm device 90. Examples of the building 2 include various facilities such as public facilities and commercial facilities. The various facilities include, for example, nursing care facilities, hospitals, schools, offices, stores, and factories. In addition, the building 2 is exemplified by a building and a condominium. That is, the building 2 targeted in the embodiment includes various buildings. A network 3 is installed in the building 2. An example of the network 3 is a LAN (Local Area Network). Each device connected to the network 3 is communicably connected via the network 3. The network 3 is connected to the Internet 4 via a gateway device. In FIG. 1, the gateway device is not shown. The fire notification system 1 includes a fire receiving device 10 and a terminal device 20, and automatically notifies a fire that has occurred in the building 2.

  The fire receiving device 10 includes a fire receiver 11 and a first sequencer 12. In the fire receiving device 10, the fire receiver 11 and the first sequencer 12 are wired by a predetermined communication cable. However, the connection between the fire receiver 11 and the first sequencer 12 may be a wireless connection. The fire receiver 11 is communicably connected to the fire detector 70. The fire receiver 11 is communicably connected to an alarm output device 81 of an alarm device 80 described later. The connection between the fire receiver 11 and the fire detector 70 is a wired connection. The connection between the fire receiver 11 and the alarm output device 81 is a wired connection. However, the connection between the fire receiver 11 and the fire detector 70 and / or the connection between the fire receiver 11 and the alarm output device 81 may be a wireless connection. As a result, the fire receiving device 10 can communicate with the fire detector 70 and the alarm device 80.

  The first sequencer 12 includes, for example, a CPU 13, a ROM (flash memory), a RAM, and a communication unit 14. In FIG. 1, illustration of ROM and RAM is omitted. The CPU 13 executes a program stored in the ROM using the RAM. The CPU 13 constitutes a control unit that controls the first sequencer 12. The communication unit 14 connects the first sequencer 12 to the network 3 and performs communication via the network 3. Thereby, the fire receiving device 10 can communicate with the server device 60 via the communication unit 14. In the fire receiving device 10, the fire place information is transmitted from the communication unit 14 to the server device 60. The description regarding this point will be described later. The fire place information will also be described later. A known fire receiver is used as the fire receiver 11. Known fire receivers are classified into, for example, P type (1st and 2nd class), R type, and GR type. Furthermore, a P-type receiver with an automatic test function is also known as a fire receiver. The model of the fire receiver 11 is appropriately determined in consideration of various circumstances. The first sequencer 12 is the same as a known sequencer in terms of hardware, and can be configured using a known sequencer. Therefore, the other description regarding the fire receiver 11 and the first sequencer 12 will be omitted as appropriate.

  The terminal device 20 is an information processing device having a communication function via the network 3. The terminal device 20 is, for example, a portable information processing device. Examples of the portable information processing apparatus include a tablet terminal, a smartphone, and a laptop computer. In the embodiment, the terminal device 20 is a tablet terminal. The connection of the terminal device 20 to the network 3 is a wireless connection. Examples of the wireless connection include connection by wireless LAN communication. The terminal device 20 is the same as a known tablet terminal in hardware. The other description regarding the terminal device 20 is mentioned later.

  The server device 60 is connected to the network 3. The server device 60 can communicate with the first sequencer 12, the terminal device 20, the second sequencer 82 of the alarm device 80 described later, and the third sequencer 92 of the fire notification device 90 described later connected to the network 3. For example, the server device 60 stores the fire place information from the first sequencer 12 described above, and transmits the fire place information in response to a request from the terminal device 20. Furthermore, the server device 60 can communicate with the cloud server 5 on the Internet 4, for example. The server device 60 is the same as a known server device in hardware.

  The fire detector 70 detects the occurrence of a fire. The fire detector 70 transmits a fire signal when a fire is detected. A fire signal from the fire detector 70 is received by the fire receiver 11. A plurality of fire detectors 70 are installed in the building 2. When the building 2 is a multi-storey building, a predetermined number of fire detectors 70 are installed on each floor. As shown in FIG. 1, it is assumed that the building 2 is a three-story building having three rooms on each floor. In this case, the fire detector 70 is installed in each room on each floor, for example. The fire detector 70 may be installed in a place of the building 2 different from the room. For example, the fire detector 70 is installed in a place such as a passage. In addition, as a place of the building 2 where the fire detector 70 is installed, a place adjacent to the building 2 is exemplified. As the fire detector 70, a known fire detector is employed. Therefore, the other description regarding the fire detector 70 will be omitted as appropriate.

  The alarm device 80 includes an alarm output machine 81 and a second sequencer 82. In the alarm device 80, the alarm output machine 81 and the second sequencer 82 are communicably connected. For example, the alarm output machine 81 and the second sequencer 82 are wiredly connected by a predetermined communication cable. However, the alarm output machine 81 and the second sequencer 82 may be connected by wireless connection. The alarm output machine 81 is a device that sounds an alarm sound. Examples of the alarm output machine 81 include emergency broadcast equipment and district sound equipment (emergency bell). When the alarm output machine 81 is an emergency broadcasting facility, the alarm sound is an audio alarm sound and is output from a speaker installed in the building 2. In FIG. 1, illustration of the speaker is omitted. When the warning output device 81 is a district acoustic device, the warning sound is a ringing sound (bell sound) output by the district acoustic device. In the fire receiving device 10, when a fire signal is received by the fire receiver 11, a ringing instruction is transmitted from the fire receiver 11 to the alarm output device 81. The alarm output machine 81 outputs an alarm sound in the building 2 when a ringing instruction is received.

  The second sequencer 82 includes, for example, a CPU, a ROM (flash memory), a RAM, and a communication unit. These units are the same as those described above included in the first sequencer 12. In FIG. 1, illustration of each part with which the 2nd sequencer 82 is provided is abbreviate | omitted. The alarm device 80 can communicate with the server device 60 via the communication unit of the second sequencer 82. In the alarm device 80, the stop instruction is received by the communication unit of the second sequencer 82. The stop instruction is an instruction to stop the alarm sound output from the alarm output machine 81. The stop instruction is transmitted from the terminal device 20 to the second sequencer 82 via the server device 60. In the alarm device 80, the second sequencer 82 transmits a stop instruction to the alarm output device 81 when the stop instruction is received by the communication unit. The fire receiver 11 can also transmit a stop signal to the alarm output device 81. The alarm output machine 81 stops the alarm sound being output when the stop signal is received. As the alarm output machine 81, a well-known emergency broadcasting facility or district sound device is used. The second sequencer 82 is the same as a known sequencer in terms of hardware, and can be configured using a known sequencer. Therefore, the other description regarding the alarm output machine 81 and the second sequencer 82 is omitted as appropriate.

  The fire reporting device 90 includes a fire reporting machine 91 and a third sequencer 92. In the fire reporting device 90, the fire reporting machine 91 and the third sequencer 92 are connected to be communicable. For example, the fire alarm device 91 and the third sequencer 92 are wired by a predetermined communication cable. However, the connection between the fire alarm device 91 and the third sequencer 92 may be a wireless connection. The fire reporting device 91 is connected to the fire engine 7 having jurisdiction over the location of the building 2 through the public line 6. The fire notifier 91 makes an emergency call (call 119) to the fire engine 7 and automatically connects to the fire engine 7 to automatically generate the fire and predetermined information related to the building 2 (for example, the name and address of the building 2). Is a device that outputs a sound.

  The third sequencer 92 includes, for example, a CPU, a ROM (flash memory), a RAM, and a communication unit. These units are the same as those described above included in the first sequencer 12. In FIG. 1, illustration of each part with which the 3rd sequencer 92 is provided is abbreviate | omitted. The fire reporting device 90 can communicate with the server device 60 via the communication unit of the third sequencer 92. In the fire notification device 90, the notification instruction is received by the communication unit of the third sequencer 92. The notification instruction is an instruction for causing the fire notification device 91 to execute an emergency notification. The notification instruction is transmitted from the terminal device 20 to the third sequencer 92 via the server device 60. In the fire reporting device 90, the third sequencer 92 transmits a reporting instruction to the fire reporting device 91 when the reporting instruction is received by the communication unit. When the notification instruction is received, the fire reporting device 91 makes an emergency call to the fire engine 7 and, after connecting to the fire engine 7, automatically outputs a predetermined information related to the occurrence of the fire and the building 2. As the fire alarm 91, a known fire alarm is used. The third sequencer 92 is the same as a known sequencer in hardware, and can be configured using a known sequencer. Therefore, the other description regarding the fire alarm 91 and the third sequencer 92 will be omitted as appropriate. The first sequencer 12, the second sequencer 82, and the third sequencer 92 may be the same sequencer in hardware.

<Terminal device>
The terminal device 20 will be described with reference to FIG. The terminal device 20 includes a CPU 21, a ROM 22, a RAM 23, a display unit 24, an operation unit 25, a sound output unit 26, and a communication unit 27. CPU21 performs arithmetic processing. The CPU 21 constitutes a control unit that controls the terminal device 20. The ROM 22 stores various processing programs executed by the CPU 21. For example, the ROM 22 stores a program for main processing (see FIGS. 2 to 4) described later. The ROM 22 stores a plurality of screen data respectively corresponding to each screen to be described later displayed on the display unit 24. Further, the ROM 22 stores floor map data corresponding to the floor map 41 of the building 2 (see the lower part of FIG. 5 described later). The floor map data is, for example, data divided for each floor. That is, when the building 2 is a three-story building (see FIG. 1), the ROM 22 stores floor map data for the first floor, floor map data for the second floor, and floor map data for the third floor. Other description regarding the floor map data will be described later. In the embodiment, the ROM 22 includes a flash memory. The RAM 23 is a storage area used when the CPU 21 executes various programs. The RAM 23 stores predetermined data used in the process during the execution of the process. In the terminal device 20, various processes are executed by the CPU 21 executing a program of the main process stored in the ROM 22. Accordingly, various processing units are configured.

  The display unit 24 displays various screens including predetermined information. As the display unit 24, a liquid crystal display or an organic EL display is exemplified. The operation unit 25 receives an input to the terminal device 20. Examples of the operation unit 25 include a touch pad, a keyboard, and a mouse. In the embodiment in which the terminal device 20 is a tablet terminal, the operation unit 25 is a touch pad. The display unit 24 and the operation unit 25 are integrated to form a touch panel. In the touch panel, the operation unit 25 using a touch pad outputs a two-dimensional coordinate position (X coordinate value and Y coordinate value) indicating a position where a user's finger of the terminal device 20 or a touch pen held by the user touches. The CPU 21 acquires the coordinate position output from the operation unit 25. Such a technique is a known technique employed in a known tablet terminal or the like. Therefore, the other description regarding this is abbreviate | omitted. In the embodiment, the user of the terminal device 20 is referred to as a “security guard”. The sound output unit 26 outputs a predetermined sound. The sound output unit 26 includes a connection unit with headphones or earphones, and a speaker.

  The communication unit 27 connects the terminal device 20 to the network 3 and performs communication via the network 3. In the embodiment in which the terminal device 20 is wirelessly connected to the network 3, the communication unit 27 corresponds to wireless LAN communication. In the terminal device 20, various types of data are transmitted / received to / from the server device 60 via the communication unit 27. The terminal device 20 is different from a known terminal device in that a main processing program is stored in the ROM 22. However, the terminal device 20 is the same as a known tablet terminal in hardware. Therefore, the terminal device 20 includes a configuration included in a known tablet terminal in addition to the above-described units. The same applies to the case where the terminal device 20 is an information processing device having a communication function different from that of the tablet terminal.

<Main processing>
The main process executed by the terminal device 20 will be described with reference to FIGS. The description of the main processing is based on the following state. That is, the fire detectors 70 that have detected a fire are the fire detector 70 installed in the second floor E room and the fire detector 70 installed in the third floor H room. The fire receiver 11 is of a type that can individually identify the place where the fire was detected (Room E, Room 2 and Room H, 3rd floor). In the embodiment, a place where a fire is detected is referred to as a “fire detection place”. Information indicating a fire detection location is referred to as “fire location information”. In the fire receiver 10, the fire receiver 11 receives a fire signal from the fire detector 70 in the second floor E room, and receives a fire signal from the fire detector 70 in the third floor H room. In the fire receiving device 10, the second floor E room and the third floor H room as fire place information are transmitted from the fire receiver 11 to the first sequencer 12, and the first sequencer 12 is in the second floor E room and the third floor H room. Receive. In the first sequencer 12, the CPU 13 transmits the received 2nd floor E room and 3rd floor H room. Accordingly, the second floor room E and the third floor room H are transmitted from the communication unit 14 to the server device 60. The server device 60 receives the second floor E room and the third floor H room. In the server device 60, the second floor room E and the third floor room H are stored in a state associated with the identification numbers (see FIG. 1).

  CPU21 which started the main process transmits a transmission request (S11). The transmission request is an instruction for requesting transmission of fire place information stored in the server device 60. The CPU 21 outputs a transmission request for a transmission request to the communication unit 27. Along with this, a transmission request is transmitted from the communication unit 27 to the server device 60. The server device 60 receives the transmission request. When the fire place information is stored, the server device 60 transmits the fire place information. When the fire place information is not stored, the server device 60 does not transmit a response to the transmission request. However, when the fire place information is not stored, the server device 60 may transmit a response indicating that the fire place information is not stored. In the embodiment, the second floor E room (identification number: 1) and the third floor H room (identification number: 2) are stored in the server device 60 as fire place information. Accordingly, the server device 60 transmits the fire place information “2nd floor E room” and “3rd floor H room”. At this time, an identification number is associated with the fire place information. The identification number is a serial number for identifying each fire place information. In FIG. 1, the identification number is “No.”.

  After executing S11, the CPU 21 determines whether or not fire place information has been acquired (S13). In the terminal device 20, the fire place information transmitted from the server device 60 is received by the communication unit 27. The CPU 21 acquires fire place information via the communication unit 27. After performing S11, when fire place information is not acquired via the communication part 27 within the predetermined period (S13: No), CPU21 returns a process to S11 and performs S11 again. That is, when the fire place information is not acquired (S13: No), the terminal device 20 repeatedly transmits a transmission request at predetermined intervals. When the fire place information is acquired (S13: Yes), the CPU 21 stores the acquired fire place information in the RAM 23 (S15). At this time, identification information transmitted in association with the fire place information is associated with the fire place information. That is, in the terminal device 20 as well as the server device 60, the identification number “1” and the fire place information “second floor E room” are stored in the RAM 23 in association with each other, and the identification number “2” and the fire place information “third floor H” are stored. “Room” is stored in association. The storage location of the fire place information may be the ROM 22.

  Next, the CPU 21 outputs an alarm sound (S17). The CPU 21 reproduces sound data corresponding to the alarm sound. Along with this, an alarm sound is output from the sound output unit 26. Subsequently, the CPU 21 displays a fire information screen (S19). The CPU 21 specifies one of the fire place information stored in the RAM 23. For example, in S19 executed first after starting the main process, the fire place information “2nd floor E room” having the identification number “1” of the fire place information stored in the RAM 23 is the minimum value. Identified. CPU21 produces | generates the fire information screen containing the identified fire place information. The fire information screen is generated using screen data corresponding to this screen stored in the ROM 22 and the specified fire place information. Subsequently, the CPU 21 outputs a display command for the generated fire information screen to the display unit 24. Accordingly, a fire information screen including fire place information is displayed on the display unit 24 (see the upper part of FIG. 5). The fire information screen shown in the upper part of FIG. 5 is a fire information screen corresponding to the case where the fire place information “second floor room E” associated with the identification number “1” is specified as the fire place information. On the fire information screen shown in the upper part of FIG. 5, the fire place information is displayed separately for the floor number and the room name.

  The fire information screen includes fire location information (floor and room name), fire detection number information, previous button 31, next button 32, map display button 33, emergency call button 34, and misinformation registration button 35. A mute button 36 and an end button 37 are included. The fire detection number information is information corresponding to the total number of fire place information stored in the RAM 23. In the embodiment, the number of fire place information that is not displayed as fire place information (fire detection number information = total number of fire place information-1) is displayed. For example, when the fire place information stored in the RAM 23 is the second floor E room (identification number: 1) and the third floor H room (identification number: 2), the fire detection number information is the total number of fire place information “2 cases” ”Is the“ other one ”subtracting the displayed fire place information“ 2nd floor room E ”. The fire detection number information may be the total number of fire place information.

  The front button 31 is operation information (operation button) associated with a switching instruction for switching the displayed fire place information to the fire place information having an identification number one smaller than the identification number of the fire place information. When the displayed fire place information is the fire place information associated with the minimum identification number, the front button 31 may be hidden or disabled (for example, grayed out). The next button 32 is operation information associated with a switching instruction for switching the displayed fire place information to the fire place information having an identification number one larger than the identification number of the fire place information. When the displayed fire place information is the fire place information associated with the largest identification number, the next button 32 may be in a non-displayed or inoperable state (for example, grayed out state).

  The map display button 33 is operation information associated with a floor map instruction. The floor map instruction is an instruction to display a floor map screen including a floor map 41 described later. The emergency call button 34 is operation information associated with the notification instruction. The misinformation registration button 35 is operation information associated with a stop instruction. The mute button 36 is operation information associated with a mute instruction. The mute instruction is an instruction to stop the output of the alarm sound from the sound output unit 26. The end button 37 is operation information associated with the end instruction. The end instruction is an instruction to end the main process.

  After executing S19, the CPU 21 determines whether or not an end instruction has been acquired (S21). The end instruction is input when the end button 37 is pressed. When pressing of the end button 37 is received by the operation unit 25, the CPU 21 acquires an end instruction. When the end instruction is acquired (S21: Yes), the CPU 21 ends the main process. When the end instruction has not been acquired (S21: No), the CPU 21 determines whether or not a switching instruction has been acquired (S23). The switching instruction is input by pressing the previous button 31 or the next button 32. When the pressing of the front button 31 is accepted by the operation unit 25, the CPU 21 issues a switching instruction to switch the displayed fire place information to the fire place information having an identification number one smaller than the identification number of the fire place information. get. When the pressing of the next button 32 is accepted by the operation unit 25, the CPU 21 issues a switching instruction to switch the displayed fire place information to the fire place information having an identification number one larger than the identification number of the fire place information. get.

  When the switching instruction is acquired (S23: Yes), the CPU 21 returns the process to S19, and switches the displayed fire information screen to the fire information screen including the fire place information corresponding to the acquired switching instruction. The operation unit 25 accepts that the next button 32 has been pressed while the displayed fire information screen is shown in the upper part of FIG. 5, and the CPU 21 has acquired a switching instruction to switch to the fire location information with one larger identification number And In this case, the CPU 21 specifies the fire place information “3rd floor H room” associated with the identification number “2” stored in the RAM 23 and generates a fire information screen including the fire place information “3rd floor H room”. . Subsequently, the CPU 21 outputs a display command for the generated fire information screen to the display unit 24. Accordingly, the fire information screen displayed on the display unit 24 is switched from the state shown in the upper part of FIG. 5 to a fire information screen in which the floor number is “3rd floor” and the room name is “Room H”. When the switching instruction has not been acquired (S23: No), the CPU 21 shifts the process to S25 of FIG.

  In S25 of FIG. 3, the CPU 21 determines whether or not a floor map instruction has been acquired. The floor map instruction is input when the map display button 33 is pressed. When the depression of the map display button 33 is received by the operation unit 25, the CPU 21 acquires a floor map instruction. When the floor map instruction has not been acquired (S25: No), the CPU 21 proceeds to S41 in FIG. When the floor map instruction is acquired (S25: Yes), the CPU 21 displays a floor map screen (S27). The CPU 21 acquires screen data and floor map data corresponding to the floor map screen from the ROM 22. The acquired floor map data is floor map data including the fire detection location indicated by the fire location information included in the displayed fire information screen. CPU21 produces | generates the floor map screen containing the floor map 41 corresponding to the fire place information contained in the fire information screen being displayed, and the acquired floor map data. The floor map screen is generated using the acquired screen data and floor map data and the fire place information included in the displayed fire information screen. Subsequently, the CPU 21 outputs a display command for the generated floor map screen to the display unit 24. Accordingly, the floor map screen is displayed on the display unit 24 (see the lower part of FIG. 5). The floor map screen displayed in this way includes the floor map 41 of the building 2 including the fire detection location indicated by the fire location information included in the fire information screen displayed immediately before the floor map screen is displayed (FIG. 5). reference).

  In the embodiment, the floor map 41 of the building 2 including the fire detection place is the entire floor on the same floor as the fire detection place. However, the floor map 41 of the building 2 including the fire detection location may be a partial range including the fire detection location in the entire floor on the same floor as the fire detection location. Furthermore, the floor map 41 of the building 2 including the fire detection location may be a floor map of the entire building 2. The range in the building 2 displayed as the floor map 41 is appropriately determined in consideration of various conditions. Each place in the building 2 included in the floor map 41 in the floor map screen is associated with place information indicating the place. Based on the lower part of FIG. 5, the location information “2nd floor D room” is associated with the display area where the second floor D room is displayed, and the location information “ The location information “second floor F room” is associated with the display area in which “second floor E room” is associated and the second floor F room is displayed. The display area of each room is specified by, for example, each two-dimensional coordinate position (X coordinate value and Y coordinate value). The place in the building 2 to which the place information is associated may be a display area other than the room.

  In the floor map screen, the floor map 41 includes facility information 42 indicating disaster prevention facilities installed in the building 2. Examples of disaster prevention equipment include fire doors, emergency stairs and digestive organs (see the lower part of FIG. 5). In addition, although illustration is abbreviate | omitted in the lower stage of FIG. 5, a fire hydrant is illustrated as disaster prevention equipment. In the floor map screen, the floor map 41 includes route information 43 indicating an evacuation route from a fire detection place to a safe place. The route information 43 is indicated by an arrow (see the lower part of FIG. 5). However, as long as the route information 43 is information that clearly indicates the evacuation route, the route information 43 may be in a mode (for example, a character) different from the arrow. On the floor map screen, the facility information 42 and / or the route information 43 may be color-coded and / or blinked with other portions. Although not shown in the lower part of FIG. 5, the floor map screen may further display a procedure for handling work to be performed by the guard. The guard can understand the type and position of the disaster prevention facility based on the facility information 42, understand the evacuation route based on the route information 43, and can recognize the corresponding procedure of work to be performed. The security guard can then perform initial fire fighting activities and / or evacuation guidance activities. The floor map screen includes floor information 41, facility information 42, route information 43, floor information 44, alert information 45, and a return button 46. The floor information 44 is information indicating the position of the floor map 41 to be displayed in the building 2 and indicates the floor. The alert information 45 is information for distinguishing the fire detection location from other locations. In the embodiment, the alert information 45 is a frame line. In the floor map screen shown in FIG. 5, the letter “E room” indicating the second floor E room as a fire detection place is surrounded by a frame line as the alert information 45 and is distinguished from other places. The alert information 45 and / or characters indicating the fire detection location (refer to “Room E” in the lower part of FIG. 5) may also be color-coded and / or blinked with other portions. The return button 46 is operation information associated with the first return instruction. The first return instruction is an instruction to display the fire information screen displayed immediately before the floor map screen is displayed.

  After executing S27, the CPU 21 determines whether or not a first return instruction has been acquired (S29). The first return instruction is input by pressing the return button 46. When pressing of the return button 46 is received by the operation unit 25, the CPU 21 acquires a first return instruction. When the first return instruction is acquired (S29: Yes), the CPU 21 returns the process to S19 in FIG. In S19, the CPU 21 displays the fire information screen displayed immediately before the floor map screen is displayed. When the first return instruction has not been acquired (S29: No), the CPU 21 determines whether an area instruction has been acquired (S31). The area instruction is an instruction for designating a predetermined place in the floor map 41 in a state where the floor map screen is displayed. For example, in the state where the floor map screen shown in the lower part of FIG. Coordinate position is acquired as an area instruction.

  When the area instruction has not been acquired (S31: No), the CPU 21 returns the process to S29 and executes S29 again. When the area instruction is acquired (S31: Yes), the CPU 21 displays a disaster information screen (S33). The CPU 21 specifies location information indicating a place in the building 2 indicated by the area instruction from the coordinate position acquired as the area instruction and the coordinate position of the display area of each place in the building 2 included in the floor map 41. For example, in the state where the floor map screen shown in the lower part of FIG. 5 is displayed, when the operation unit 25 receives a press into the area of the room D in the floor map 41, the CPU 21 has been acquired as an area instruction. From the coordinate position and the coordinate position of the display area of each place in the building 2 included in the floor map 41, the place information “second floor D room” is specified. In the embodiment, the location information specified with the acquisition of the area instruction is referred to as “designated location information”. The CPU 21 generates a disaster information screen including the specified designated place information. The disaster information screen is generated using screen data corresponding to this screen stored in the ROM 22 and designated location information. The CPU 21 outputs a display instruction for the disaster information screen to the display unit 24. Along with this, the disaster information screen is displayed on the display unit 24 (see FIG. 6).

  The disaster information screen includes a numeric keypad 51, an input box 52, a confirmation button 53, and a return button 54 in addition to the designated location information. On the disaster information screen, input of the number of victims in the place in the building 2 indicated by the designated place information is accepted. The numeric keypad 51 is used when inputting the number of victims. The guard presses the numeric keypad 51 and inputs the number of victims. In the input box 52, when the operation unit 25 accepts pressing of a predetermined numeric key included in the numeric keypad 51, the accepted numeric value is displayed. The confirmation button 53 is operation information associated with the confirmation instruction. The confirmation instruction is an instruction to use the numerical value displayed in the input box 52 as the confirmation value. When the numerical value is not displayed in the input box 52, the confirmation button 53 may be hidden or inoperable (for example, grayed out). The return button 54 is operation information associated with the second return instruction. The second return instruction is an instruction to display the floor map screen that was displayed immediately before the display of the disaster information screen.

  After executing S33, the CPU 21 determines whether or not a second return instruction has been acquired (S35). The second return instruction is input by pressing the return button 54. When pressing of the return button 54 is accepted by the operation unit 25, the CPU 21 acquires a second return instruction. When the second return instruction is acquired (S35: Yes), the CPU 21 returns the process to S27. In S27, the CPU 21 displays the floor map screen displayed immediately before. When the second return instruction has not been acquired (S35: No), the CPU 21 determines whether a confirmation instruction has been acquired (S37). The guard presses the numeric keypad 51 and inputs the number of victims. When pressing of a predetermined numeric key included in the numeric keypad 51 is received by the operation unit 25, the CPU 21 acquires a numerical value output from the operating unit 25 and causes the input box 52 to display the acquired numerical value. Thereafter, the guard presses the confirmation button 53. When the pressing of the confirmation button 53 is accepted by the operation unit 25, the CPU 21 acquires a confirmation instruction. At this time, the CPU 21 acquires the numerical value displayed in the input box 52 as the disaster victim value, and further acquires the specified location information included in the disaster information screen being displayed.

  When the confirmation instruction has not been acquired (S37: No), the CPU 21 returns the process to S35 and executes S35 again. When the confirmation instruction is acquired (S37: Yes), the CPU 21 transmits rescue information (S39). The rescue information includes a disaster victim value and designated location information acquired together with the confirmation instruction. The transmission destination of the rescue information is the server device 60. The CPU 21 outputs a rescue information transmission command to the communication unit 27. Along with this, rescue information is transmitted from the communication unit 27 to the server device 60. In the server device 60, the rescue information is received. In the server device 60, the received rescue information is stored. That is, in the server device 60, the victim value and the designated location information included in the received rescue information are stored in association with each other.

  After executing S39, the CPU 21 returns the process to S19 of FIG. Thereafter, the CPU 21 executes the processes after S19 again. In this case, the fire information screen displayed in S19 is a screen including the same fire place information as the fire information screen displayed in S19 executed last time. However, when a plurality of fire place information is stored in the RAM 23, in S19 after execution of S39, a fire information screen including fire place information different from the fire information screen displayed in S19 executed last time is displayed. You may do it. Which fire information screen is displayed is appropriately determined in consideration of various circumstances.

  In S41 of FIG. 4, the CPU 21 determines whether or not a notification instruction has been acquired. The notification instruction is input by pressing the emergency notification button 34 in the fire information screen (see the upper part of FIG. 5). For example, the guard moves to or near the fire detection location indicated by the fire location information in accordance with the fire location information included in the fire information screen. The guard presses the emergency call button 34 when the occurrence of the fire can be confirmed. When the pressing of the emergency notification button 34 is accepted by the operation unit 25, the CPU 21 acquires a notification instruction. When the report instruction is acquired (S41: Yes), the CPU 21 transmits the report instruction (S43). The transmission destination of the notification instruction is the server device 60. The CPU 21 outputs a notification instruction transmission command to the communication unit 27. Along with this, a notification instruction is transmitted from the communication unit 27 to the server device 60. The server device 60 receives the notification instruction. The server device 60 transmits the received notification instruction to the third sequencer 92. Thereafter, in the fire notification device 90, as described above, an emergency notification to the fire engine 7 is executed. After executing S43, the CPU 21 ends the main process.

  When the notification instruction has not been acquired (S41: No), the CPU 21 determines whether or not a stop instruction has been acquired (S45). The stop instruction is input by pressing the misinformation registration button 35. For example, the guard moves to or near the fire detection location indicated by the fire location information in accordance with the fire location information included in the fire information screen. If the security guard cannot confirm the occurrence of the fire, the guard presses the misinformation registration button 35. When the pressing of the misinformation registration button 35 is accepted by the operation unit 25, the CPU 21 acquires a stop instruction. When the stop instruction has not been acquired (S45: No), the CPU 21 shifts the process to S53. When the stop instruction is acquired (S45: Yes), the CPU 21 has acquired the fire location information stored in the RAM 23 in association with the fire location information that matches the fire location information included in the displayed fire information screen. Information is stored (S47).

  Next, the CPU 21 determines whether or not the acquired information is stored in association with all the fire place information stored in the RAM 23 (S49). When the acquired information is not stored in association with all the fire place information stored in the RAM 23 (S49: No), the CPU 21 returns the process to S19 in FIG. Thereafter, the CPU 21 executes the processes after S19 again. In this case, the fire information screen displayed in S19 may be a fire information screen including fire place information that is not associated with information already acquired in the RAM 23. It is confirmed that no fire has occurred at the fire detection location indicated by the fire location information associated with the acquired information, and such a fire detection location is subject to confirmation again in an emergency situation. This can be prevented.

  When the acquired information is stored in association with all the fire place information stored in the RAM 23 (S49: Yes), the CPU 21 transmits a stop instruction (S51). The transmission destination is the server device 60. The CPU 21 outputs a stop instruction transmission command to the communication unit 27. Along with this, a stop instruction is transmitted from the communication unit 27 to the server device 60. The server device 60 receives a stop instruction. The server device 60 transmits the received stop instruction to the second sequencer 82. Thereafter, in the alarm device 80, as described above, the alarm sound being output by the alarm output device 81 is stopped. After executing S51, the CPU 21 ends the main process. When the number of fire place information stored in the RAM 23 is one, S49 is always affirmed (S49: Yes).

  In S53, the CPU 21 determines whether a mute instruction has been acquired. The mute instruction is input by pressing the mute button 36. The guard presses the mute button 36 when stopping the output of the alarm sound from the sound output unit 26. When the depression of the mute button 36 is accepted by the operation unit 25, the CPU 21 acquires a mute instruction. When the mute instruction is acquired (S53: Yes), the CPU 21 stops the reproduction of the sound data corresponding to the alarm sound (S55). Accordingly, the output of the alarm sound from the sound output unit 26 is stopped. After executing S55, the CPU 21 returns the process to S21 of FIG. 2, and executes the processes after S21 again.

<Effect of embodiment>
According to the embodiment, the following effects can be obtained.

  (1) When the fire place information is acquired, the terminal device 20 outputs an alarm sound and displays a fire information screen including the fire place information (S13: Yes, S17, S19 in FIG. 2 and the upper part of FIG. 5). reference). The acquired fire place information is stored in the RAM 23 (see S15 in FIG. 2). In the terminal device 20, when the map display button 33 is pressed by the guard while the fire information screen is displayed, the floor map instruction is acquired and the floor map screen is displayed (S25 in FIG. 3: Yes, (See S27 and the lower part of FIG. 5). The floor map screen includes a floor map 41 including a fire detection location indicated by the fire location information included in the fire information screen. Therefore, the alarm sound from the sound output unit 26 can notify the security guard that a fire has occurred or that a fire may have occurred. The security guard can recognize the fire detection location from the fire location information on the fire information screen. The security guard can display the floor map screen while recognizing the fire detection location. The security guard can consider the response to the fire based on the floor map 41 in the floor map screen. In the fire information screen and the floor map screen (see FIG. 5), the background color of the screen may be, for example, a color excellent in visibility even in smoke. For example, in each screen described above, the background color is pink.

  (2) In the terminal device 20, when a predetermined location in the building 2 included in the floor map 41 is pressed by a security guard while the floor map screen is displayed, an area instruction corresponding to the pressed location is issued. The designated location information is acquired, and the disaster information screen including the designated location information is displayed (see S31 in FIG. 3: Yes, S33 and FIG. 6). In the terminal device 20, when the confirmation button 53 is pressed by the guard while the disaster information screen is displayed, the victim value and the specified location information that are input according to the display of the disaster information screen are acquired together with the confirmation instruction. Then, rescue information including the victim value and designated location information is transmitted to the server device 60 (see S37 in FIG. 3: Yes, S39). In the server device 60, the victim value and the designated location information are stored in association with each other. Therefore, by accessing the server device 60, a plurality of persons can share the number of victims and the location where the victims are located. Smooth rescue operations are possible. In the disaster information screen (see FIG. 6), the background color of the screen may be, for example, a color having excellent visibility (for example, pink) in smoke as in the fire information screen and the floor map screen.

  (3) In the terminal device 20, when the emergency notification button 34 is pressed by the security guard while the fire information screen is displayed, the notification instruction is acquired and the notification instruction is transmitted to the fire notification device 90 ( (See S41 in FIG. 4: Yes, S43). In the fire reporting device 90, the third sequencer 92 receives a reporting instruction, and an emergency report from the fire reporting device 91 to the fire engine 7 is executed. Therefore, an emergency call can be executed from the terminal device 20. Prompt emergency call is possible.

  (4) In the terminal device 20, when the misinformation registration button 35 is pressed by a security guard while the fire information screen is displayed, a stop instruction is acquired, and the fire place information stored in the RAM 23 is being displayed. The acquired information is stored in association with the fire place information that matches the fire place information included in the fire information screen (see S45 in FIG. 4: Yes, S47). And when acquired information is linked | related and memorize | stored with respect to all the fire place information memorize | stored in RAM23, a stop instruction | indication is transmitted to the alarm device 80 (refer S49 of FIG. 4: Yes, S51). In the alarm device 80, the stop instruction is received by the second sequencer 82, and the alarm sound being output is stopped by the alarm output device 81. Therefore, it is possible to avoid a state in which an alarm sound continues to sound. For example, when the fire detector 70 malfunctions, the alarm sound can be easily stopped.

<Modification>
The embodiment can also be performed as follows. Some configurations of the modifications shown below can be appropriately combined and employed. Hereinafter, points different from the above will be described, and description of similar points will be omitted as appropriate.

  (1) In the above, the notification instruction is transmitted from the terminal device 20 to the third sequencer 92 of the fire notification device 90 via the server device 60 (see S43 in FIG. 4). The terminal device 20 and the third sequencer 92 may be directly communicated with each other via the network 3. In this case, the transmission destination of the notification instruction is the third sequencer 92 in S43 of FIG. The notification instruction is transmitted from the communication unit 27 to the third sequencer 92. The stop instruction is transmitted from the terminal device 20 to the second sequencer 82 via the server device 60 (see S51 in FIG. 4). The terminal device 20 and the second sequencer 82 may be directly communicated via the network 3. In this case, the transmission destination of the stop instruction is the second sequencer 82 in S51 of FIG. The stop instruction is transmitted from the communication unit 27 to the second sequencer 82.

  (2) In the above, the fire receiving device 10 includes the fire receiver 11 and the first sequencer 12. In the fire receiving device 10, the fire receiver 11 and the first sequencer 12 are connected so as to be communicable. The fire receiving device may be a single device in which the fire receiver and the first sequencer are integrated. In the integrated fire receiving device, when a fire signal from the predetermined fire detector 70 is received, the CPU of the fire receiving device transmits a ringing instruction to the alarm output device 81 of the alarm device 80. In the integrated fire receiving device, when a fire signal from a predetermined fire detector 70 is received, the CPU of the fire receiving device acquires this fire signal, and the fire detector 70 that detects the fire is installed. Fire location information indicating the fire detection location is transmitted from the communication unit of the fire receiving device to the server device 60. Furthermore, the fire receiving device may be a device having a server function equivalent to that of the server device 60. In this case, the server device 60 is omitted, and the fire receiving device functions as the server device 60 described above.

  The alarm device 80 includes an alarm output machine 81 and a second sequencer 82. In the alarm device 80, the alarm output machine 81 and the second sequencer 82 are communicably connected. The alarm device may be a single device in which the alarm output machine and the second sequencer are integrated. In the integrated alarm device, when a stop instruction from the terminal device 20 is received, the CPU of the alarm device acquires the stop instruction via the communication unit of the alarm device, and instructs the configuration corresponding to the alarm output machine to stop. Is output. The fire notification device 90 includes a fire notification device 91 and a third sequencer 92. In the fire reporting device 90, the fire reporting machine 91 and the third sequencer 92 are connected to be communicable. The fire reporting device may be a single device in which the fire reporting machine and the third sequencer are integrated. In the integrated fire notification device, when a notification instruction from the terminal device 20 is received, the CPU of the fire notification device acquires the notification instruction via the communication unit of the fire notification device, and corresponds to a fire notification device. A notification instruction is output.

  (3) In the above, the fire detection location is a predetermined range of the building 2 divided by the unit in which the fire detector 70 is provided, and the fire location information is information indicating the fire detection location according to the aforementioned range. did. For example, the fire detection location and the fire location information when a fire is detected by the fire detector 70 installed in the second floor E room is the second floor E room. That is, the fire detection location is a unit of each room provided with one fire detector 70, and the fire detection location information is a combination of the floor number and the room name of each room. The fire detection location may be set to a predetermined range monitored by a plurality of fire detectors 70. For example, the fire detection place may be divided for each floor number. Fire place information is indicated by the number of floors. In this case, for example, even if a fire is detected by any of the fire detectors 70 installed in the second floor D room, the second floor E room, and the second floor F room, the fire detection place is on the second floor of the building 2. There is fire place information on the second floor. In addition, the fire detection location and the fire location information may be set in a range such as the second floor east side or the second floor west side.

  (4) In the above, the floor map data is stored in the ROM 22 in the terminal device 20. The floor map data may be stored in the server device 60, and the floor map data may be transmitted from the server device 60 to the terminal device 20. The server device 60 transmits the floor map data together with the identification number and the fire place information. The floor map data is data corresponding to the floor map 41 including the fire detection location indicated by the fire location information to be transmitted. In addition, when S25 of the main process (see FIGS. 2 to 4) is affirmed (see S25: Yes in FIG. 3), before executing S27, a floor map data transmission request is transmitted to the server device 60. You may make it acquire floor map data from the server apparatus 60. FIG. In this case, the transmission request includes the fire place information included in the displayed fire information screen. In the server device 60, the floor map data to be transmitted is specified according to the fire place information.

  (5) In the above, when the fire place information is acquired by the terminal device 20 (see S13 in FIG. 2: Yes), an alarm sound is output from the sound output unit 26 (see S17 in FIG. 2). In the terminal device 20, when fire place information is acquired (refer to S13 of FIG. 2: Yes), the light emitting body (not shown) provided in the terminal device 20 is turned on or blinked together with the alarm sound or instead of the alarm sound. You may do it. When the fire place information is acquired by the terminal device 20 (see S13 in FIG. 2: Yes), the fire detection place indicated by the fire place information included in the fire information screen is displayed on the fire information screen displayed in S19 in FIG. You may make it include the floor map 41 containing. In this case, the map display button 33 may be omitted on the fire information screen, and S25 to S29 in FIG. 3 may be omitted in the main process (see FIGS. 2 to 4). In the main process, when S23 in FIG. 2 is negative (see S23: No), the process proceeds to S31 in FIG. If S31 is negative (see S31: No), the process proceeds to S41 of FIG.

  (6) In the above, the number of terminal devices 20 in the fire alarm system 1 is one. The fire alarm system 1 may include a plurality of terminal devices 20. When there are a plurality of guards, each guard operates each terminal device 20. In this case, the main processing (see FIGS. 2 to 4) described above is executed by each of the plurality of terminal devices 20. In connection with S47 of FIG. 4, the terminal device 20 may transmit confirmation information to the server device 60. The confirmation information includes the identification information, the fire place information, and the acquired information stored in association with each other in S47. In the confirmation information, the identification information may be omitted. The server device 60 receives the confirmation information from the terminal device 20, and stores the acquired information in association with the identification information and the fire location information that match the identification information and the fire location information included in the confirmation information. The server device 60 transmits confirmation information to each of the plurality of terminal devices 20. In the terminal device 20, the acquired information is stored in association with the identification information and the fire place information that match the identification information and the fire place information included in the confirmation information. This storage can be omitted in the terminal device 20 that is the transmission source of the confirmation information. You may make it exclude the terminal device 20 of the transmission source of confirmation information from the terminal device 20 used as the transmission destination of confirmation information. According to such a configuration, the identification information, the fire place information, and the acquired information can be synchronized by the plurality of terminal devices 20. The occurrence of a situation in which a plurality of guards confirm the same fire detection location can be suppressed.

  (7) In the above, when the occurrence of a fire is detected by the fire detector 70, the fire place information is stored in the server device 60 (see FIG. 1). Further, the server device 60 receives the rescue information transmitted from the terminal device 20 in S39 of FIG. 3, and stores the disaster victim value and the designated location information. The server device 60 may transmit the above-described information stored in the own device to the cloud server 5 via the Internet 4. The cloud server 5 stores the received information described above. It becomes possible to acquire the above-described information from the cloud server 5 using a communication terminal that can be connected to the Internet 4. From the outside of the building 2, it is possible to confirm the fire occurrence location and rescue information (disaster victim value and designated location information). You may make it access to the above-mentioned each information memorize | stored in the cloud server 5 through predetermined | prescribed authentication. It is also possible to send an e-mail including the above-mentioned information stored in the cloud server 5 with a pre-registered mail address as a destination.

DESCRIPTION OF SYMBOLS 1 Fire alarm system, 2 Building, 3 Network, 4 Internet 5 Cloud server, 6 Public line, 7 Fire engine, 10 Fire receiver 11 Fire receiver, 12 First sequencer, 13 CPU, 14 Communication part 20 Terminal device, 21 CPU, 22 ROM, 23 RAM, 24 display section 25 operation section, 26 sound output section, 27 communication section, 31 previous button 32 next button, 33 map display button, 34 emergency call button 35 false alarm registration button, 36 mute button, 37 End button 41 Floor map, 42 Equipment information, 43 Route information, 44 Floor information 45 Alert information, 46 Back button, 51 Numeric keypad, 52 Input box 53 Confirm button, 54 Return button, 60 Server device, 70 Fire detector 80 Alarm device , 81 Alarm output machine, 82 The sequencer 90 fire warning apparatus, 91 fire notifier, 92 third sequencer

Claims (8)

In the control unit that controls the terminal device included in the fire alarm system installed in the building that automatically notifies the fire that occurred in the building,
When a fire is detected by the fire detector installed in the building, the fire location information indicating the fire detection location where the fire detector is installed is connected to the network installed in the building. A first acquisition process to be acquired via the communication unit of the terminal device;
When the said fire place information is acquired, the program which performs the 1st display process which displays the floor map of the said building containing the said fire detection place on the display part of the said terminal device. The program is stored in the control unit.
When the fire place information is acquired, the fire place information and map display operation information corresponding to the display of the floor map, a second display process for displaying on the display unit,
A second acquisition process of acquiring a floor map instruction for instructing display of the floor map via the operation unit of the terminal device in a state where the map display operation information is displayed on the display unit. ,
The program according to claim 1, wherein the first display process is executed when the fire place information and the floor map instruction are acquired. In the second display process, when the fire location information is acquired, an alarm output from an alarm device installed in the building that outputs an alarm sound in response to the occurrence of a fire detected by the fire detector A process of further displaying stop operation information corresponding to the sound stop on the display unit,
The program is stored in the control unit.
In a state where the stop operation information is displayed on the display unit, a third acquisition process for acquiring a stop instruction for instructing stop of an alarm sound output by the alarm device via the operation unit;
3. The program according to claim 2, wherein when the stop instruction is acquired, a first transmission process for transmitting the stop instruction from the communication unit to the alarm device is executed. In the second display process, when the fire location information is acquired, emergency call operation information corresponding to execution of an emergency call from a fire reporting device installed in the building to a fire department having jurisdiction over the location of the building is displayed. And a process of displaying on the display unit.
The program is stored in the control unit.
In a state where the emergency call operation information is displayed on the display unit, a fourth acquisition process for acquiring a notification instruction for instructing execution of an emergency call in the fire notification device via the operation unit;
The program according to claim 2 or 3, wherein, when the notification instruction is acquired, a second transmission process for transmitting the notification instruction from the communication unit to the fire notification apparatus is performed. The program is stored in the control unit.
In a state where the floor map is displayed on the display unit, a fifth acquisition process for acquiring an area instruction for designating a predetermined location of the building in the floor map via the operation unit of the terminal device;
When the area instruction is acquired, a third display process for causing the display unit to display disaster information corresponding to the identification of the number of disaster victims in the predetermined place;
In a state where the disaster information is displayed on the display unit, a sixth acquisition process for acquiring a disaster victim value indicating the number of the disaster victims via the operation unit;
When the disaster victim value is acquired, the rescue information including the disaster victim value and designated location information indicating the predetermined location is transmitted from the communication unit to a server device connected to the network. The program according to any one of claims 1 to 4, wherein the program executes transmission processing.   The first display processing includes facility information indicating disaster prevention equipment including at least one of a fire door, an emergency staircase, a digester, and a fire hydrant installed in the building, and route information indicating an evacuation route from a fire detection location. The program according to any one of claims 1 to 5, which is a process of causing the display unit to display the floor map including one or both of the above. A terminal device included in a fire alarm system installed in the building that automatically notifies of a fire that has occurred in a building,
A communication unit connected to a network installed in the building;
When the occurrence of a fire is detected by the fire detector installed in the building, the fire location information indicating the fire detection location where the fire detector where the fire was detected is installed is acquired via the communication unit. An acquisition processing unit;
A display unit;
A terminal device comprising: a first display processing unit configured to display a floor map of the building including the fire detection location on the display unit when the fire location information is acquired. A fire alarm system installed in the building, including a fire receiving device and a terminal device connected via a network, and automatically informing a fire that has occurred in a building,
The fire receiving device transmits fire place information indicating a fire detection place where the fire detector that detects the fire is installed when the occurrence of a fire is detected by a fire detector installed in the building, A first communication unit connected to the network;
The terminal device
A second communication unit connected to the network;
A first acquisition processing unit for acquiring the fire place information via the second communication unit;
A display unit;
A fire notification system comprising: a first display processing unit configured to display a floor map of the building including the fire detection location on the display unit when the fire location information is acquired.

Images