JP2024032909A - Control system, information terminal, processing method, control method, and program - Google Patents

Abstract

[Problem] To reduce the time required for evacuation when a disaster occurs. A control system 1 includes an acquisition section 11 and an output processing section 12. The acquisition unit 11 acquires occurrence information regarding the occurrence of a disaster that requires evacuation from a facility. The output processing unit 12 generates route information regarding an evacuation route in the facility using the acquisition of the occurrence information as a trigger, and performs output according to the route information. [Selection diagram] Figure 1

Description

The present disclosure generally relates to a control system, an information terminal, a processing method, a control method, and a program. More specifically, the present disclosure relates to a control system related to the occurrence of a disaster that requires evacuation from a facility, an information terminal that communicates with the control system, a processing method for the control system, a control method for the information terminal, and a program.

Patent Document 1 discloses a residential fire alarm. This residential fire alarm includes a detection section that detects fire factors such as smoke and heat, and a control section that controls the output of an acoustic alarm such as a buzzer when a fire is detected. Additionally, residential fire alarms are provided with a light-emitting display section that emits light toward the floor surface at the same time as outputting an acoustic alarm. According to this residential fire alarm, when a fire breaks out at night, etc., it is possible to secure footing and quickly find an evacuation route.

Japanese Patent Application Publication No. 2006-39818

When a disaster such as a fire that requires evacuation from a facility occurs, it is desirable to further reduce the time required for evacuation by considering the entire facility.

The present disclosure has been made in view of the above reasons, and aims to provide a control system, an information terminal, a processing method, a control method, and a program that can reduce the time required for evacuation when a disaster occurs.

A control system according to one aspect of the present disclosure includes an acquisition unit and an output processing unit. The acquisition unit acquires occurrence information regarding the occurrence of a disaster that requires evacuation from the facility. The output processing unit generates route information regarding an evacuation route in the facility using the acquisition of the occurrence information as a trigger, and outputs an output according to the route information to an output destination different from an acquisition source of the occurrence information. Execute.

An information terminal according to one aspect of the present disclosure communicates with the above control system. The information terminal includes a communication unit that communicates with the control system, and a display unit that displays the evacuation route based on information for displaying the evacuation route received by the communication unit.

A processing method according to one aspect of the present disclosure is a processing method for a control system. The processing method includes an acquisition step and an output processing step. In the acquisition step, occurrence information regarding the occurrence of a disaster that requires evacuation from the facility is acquired. In the output processing step, route information regarding an evacuation route in the facility is generated using the acquisition of the occurrence information as a trigger, and output according to the route information to an output destination different from the source from which the occurrence information is acquired. Execute.

A program according to one aspect of the present disclosure is a program for causing one or more processors to execute the above processing method.
A control method according to one aspect of the present disclosure is a method of controlling an information terminal including a communication unit and a display unit. The control method includes a receiving step and a displaying step. In the receiving step, route information regarding an evacuation route in the facility is generated using the acquisition of occurrence information regarding the occurrence of a disaster that requires evacuation from the facility as a trigger, and is sent to an output destination different from the source from which the occurrence information is acquired. , the communication unit receives information for displaying an evacuation route output according to the route information. In the display step, the evacuation route is displayed on the display unit based on the information for displaying the evacuation route received by the communication unit.
A program according to one aspect of the present disclosure is a program for causing one or more processors to execute the above control method.

According to the present disclosure, there is an advantage that the time required for evacuation can be shortened when a disaster occurs.

FIG. 1 is a block diagram of a disaster prevention system including a control system according to an embodiment. FIG. 2 is a conceptual diagram when the above disaster prevention system is applied to a facility (a detached house). FIG. 3 is a conceptual diagram for explaining route information in the above control system. FIG. 4 is a conceptual diagram regarding the screen display of route information in the control system mentioned above. FIG. 5 is a sequence diagram illustrating the operation of the above disaster prevention system.

(1) Overview Each figure described in the following embodiments is a schematic diagram, and the ratio of the size and thickness of each component in each figure does not necessarily reflect the actual size ratio. Not necessarily.

The control system 1 according to this embodiment includes an acquisition section 11 and an output processing section 12, as shown in FIG. Here, the control system 1 is assumed to be one control device 10 housed in one casing, as an example. The control device 10 is, for example, a HEMS (Home Energy Management System) controller installed within the facility 200 (see FIG. 2). However, the control system 1 is not limited to the control device 10 housed in one housing, and may include a plurality of control devices with multiple functions provided in a distributed manner, or may be installed outside the facility 200. It may also include a server device.

In the following, it is assumed that the facility 200 is a detached house. However, the facility 200 may also be a housing complex (apartment). Furthermore, the facilities 200 are not limited to residences, but include non-residential facilities such as office buildings, theaters, movie theaters, public halls, playgrounds, complexes, restaurants, department stores, schools, hotels, inns, hospitals, nursing homes, and kindergartens. , libraries, museums, art galleries, underground malls, stations, airports, etc.

The acquisition unit 11 acquires occurrence information regarding the occurrence of a disaster that requires evacuation from the facility 200 . In the following, it is assumed that the disaster is a fire. However, disasters are not limited to fires, but may also include floods, earthquakes, etc. The disaster may also be gas leakage, generation of CO (carbon monoxide) due to incomplete combustion, or the like.

Further, the occurrence information is, for example, information indicating the detection result of a disaster by one or more detectors installed in the facility 200 to detect the occurrence of a disaster in the facility 200. As mentioned above, since the disaster here is a fire, it is assumed that the detector is a fire detector. In particular, the detector is a residential fire alarm 2 (hereinafter simply referred to as "alarm 2"), which has a detection function to detect the occurrence of a fire and an alarm function to issue an alarm when the occurrence of a fire is detected. ). For example, the alarm device 2 outputs a sound such as an alarm sound when a fire occurs. In short, here, as an example, the source of the occurrence information is the alarm device 2 installed in the facility 200. However, the source of the occurrence information is not limited to the alarm device 2 inside the facility 200, but may be a server device outside the facility 200. For example, if the disaster is an earthquake, the configuration may be such that information regarding an earthquake early warning is received from an external server device as the occurrence information.

The output processing unit 12 generates route information regarding the evacuation route R1 (see FIG. 4) in the facility 200 using the acquisition of the occurrence information as a trigger, and performs output according to the route information. "Execution of output according to route information" may be, for example, sending a control signal to control the external device 3 (see FIGS. 1 and 2), or outputting a route to the display unit D1 (see FIG. 1). It may also be a display of information.

According to this configuration, since the output processing unit 12 generates route information and performs output according to the route information, it is possible to reduce the time required for evacuation when a disaster occurs.

Functions similar to those of the control system 1 described above may be realized by a processing method, a (computer) program, a non-temporary recording medium on which a (computer) program is recorded, or the like.

(2) Details Hereinafter, the overall configuration of the control system 1 according to the present embodiment and the disaster prevention system 100 including the control system 1 will be described in detail with reference to FIGS. 1 to 5.

(2.1) Overall configuration As shown in FIG. 1, the disaster prevention system 100 according to the present embodiment includes a control device 10 (control system 1) and one or more (here, five) alarms 2 (detectors). ). The five alarm devices 2 are installed in the facility 200 to detect the occurrence of a fire (disaster) in the facility 200. Further, the disaster prevention system 100 further includes one or more (here, three) external devices 3, an information terminal 4, and an external server 5, as shown in FIG. As described above, the facility 200 is a detached house.

(2.2) Alarm Each alarm 2 is, for example, a battery-powered fire alarm. However, the alarm 2 is a fire alarm that is electrically connected to an external power source (for example, a commercial power system) and is driven by converting AC power (for example, effective value 100 V) supplied from the external power source into DC current. There may be.

The five alarm devices 2 are so-called linked alarm devices, and even if any alarm device 2 detects a fire, it will work in conjunction with the other alarm devices 2 (together with the other alarm devices 2) and emit an alarm sound. It is configured to issue an alarm. The alarm device 2 (linked source) located at the fire source issues an alarm sound, for example, "Vueview fire." On the other hand, the other alarm device 2 (linked destination) issues an alarm sound that allows the location of the fire source to be identified. Here, as an example, any one of the five alarm devices 2 functions as a master device, and the remaining alarm devices 2 function as slave devices. The alarm device 2 that is the parent device stores identification information of the alarm devices 2 that are other slave devices. Hereinafter, the alarm device 2 of the parent device may be referred to as the first alarm device 2A, and the alarm device 2 of the slave device may be referred to as the second alarm device 2B.

It is assumed that the five alarm devices 2 are installed on the ceiling surfaces of three rooms, a hallway, and a staircase on the first floor of the facility 200, respectively. Here, it is assumed that the facility 200 is divided into a plurality of management areas A0 (see FIG. 3). In the following, for convenience of explanation, it is assumed that the facility 200 is divided into five management areas A0 based on the area where the alarm device 2 is installed on the first floor of the facility 200. In other words, the area where the alarm device 2 is not installed (the washroom L1 in FIG. 3) will be explained excluding from the management area A0. However, the area where the alarm device 2 is not installed may also be one management area A0.

Among the five management areas A0, three rooms are called the first management area A1, the second management area A2, and the third management area A3, and the hallway leading to the entrance L2 is called the fourth management area A4. The stairs are called a fifth management area A5. The first management area A1 is a kitchen and is connected to the back door L3. The second management area A2 is a bedroom with a window L4. An electric window shutter, which will be described later, is installed on the outside of the window L4. The third management area A3 is a living room. It is preferable that the first alarm device 2A (master device) is installed at a position where it can communicate with all four second alarm devices 2B (slave devices). As an example, the first alarm device 2A is installed in the fifth management area A5, and the four second alarm devices 2B are installed in the first to fourth management areas A1 to A4, respectively.

The alarm device 2 will be described below with reference to FIG. The second alarm device 2B has substantially the same functions as the first alarm device 2A, except for some functions. Therefore, descriptions of the functions of the second alarm device 2B that are substantially common to the first alarm device 2A will be omitted as appropriate, and descriptions of the functions of the second alarm device 2B that are different from the functions of the first alarm device 2A will be omitted. In some cases, explanations may be given as appropriate.

As shown in FIG. 1, each alarm device 2 includes a control section 20, a first communication section 21, a second communication section 22, a battery 23, a notification section E1 (operating light 24 and an acoustic section 25), and a detection section 26. have. However, the second alarm device 2B does not need to include the first communication section 21. The battery 23 is, for example, a lithium battery, and the alarm device 2 is operated by power supplied from the battery 23.

The control unit 20 includes, for example, a computer system. A computer system mainly includes one or more processors and one or more memories as hardware. The functions of the control unit 20 are realized by one or more processors executing programs recorded in one or more memories of the computer system. The program is pre-recorded in one or more memories of the computer system. Note that the program may be provided through a telecommunications line, or may be provided by being recorded on a non-temporary recording medium readable by a computer system, such as a memory card, an optical disk, or a hard disk drive.

The control unit 20 stores unique identification information of its own machine. In particular, the control unit 20 of the first alarm device 2A stores unique identification information of the four second alarm devices 2B and the control device 10. The control unit 20 of the second alarm device 2B stores unique identification information of the first alarm device 2A.

The control unit 20 controls the first communication unit 21, the second communication unit 22, the notification unit E1, the detection unit 26, and the like. The control unit 20 also controls a power supply circuit that generates operating power for various circuits from the DC power of the battery 23.

The detection unit 26 is configured to detect smoke associated with the occurrence of a fire, and the detected amount (for example, voltage value) changes depending on the amount (concentration) of smoke generated. The detection unit 26 is, for example, a photoelectric sensor that detects smoke. The detection section 26 has a light emitting section 261 and a light receiving section 262, as shown in FIG. The generation of smoke is detected by the light receiving element of the light receiving part 262 detecting scattered light generated when the light emitted from the light emitting element of the light emitting part 261 is reflected by smoke particles. Of course, the detection unit 26 may be configured as a heat-sensitive type that detects the occurrence of a fire according to the heat generated by the occurrence of a fire. The control unit 20 compares the detection amount of the detection unit 26 with a threshold value, and determines that a fire has occurred if the detection amount exceeds the threshold value.

The first communication unit 21 and the second communication unit 22 transmit and receive wireless signals using radio waves as a medium. The first communication unit 21 is configured to communicate with the control device 10. The second communication unit 22 is configured to communicate with other alarm devices 2. Each of the first communication unit 21 and the second communication unit 22 includes an antenna, a transmitting circuit, and a receiving circuit. The transmitting circuit modulates the data input from the control unit 20 into a wireless signal and transmits it via the antenna. The receiving circuit demodulates the radio signal received via the antenna and outputs the demodulated data to the control unit 20.

The first communication unit 21 performs wireless communication based on a specified low power wireless station, and performs wireless communication with the control device 10 using, for example, radio waves in the 920 MHz band. On the other hand, the second communication unit 22 performs wireless communication in accordance with, for example, "wireless station for low power security system" specified in Article 6, Paragraph 4, Item 3 of the Radio Act Construction Regulations, and uses, for example, 426 MHz. Wireless communication is performed with other alarm devices 2 using radio waves in the frequency band. That is, the frequency band used for communication with the control device 10 and the frequency band used for communication between the alarm devices 2 are different from each other. Note that the first communication section 21 and the second communication section 22 may be configured as one communication section that is integrated with each other, or at least a portion of the antenna, the transmitting circuit, and the receiving circuit may be shared. .

The first alarm device 2A functions as a base unit that communicates with both the second alarm devices 2B and the control device 10, and thus has a first communication section 21 and a second communication section 22. On the other hand, each second alarm device 2B functioning as a slave device does not have a function of communicating with the control device 10. That is, each second alarm device 2B does not have the first communication section 21. In short, each second alarm device 2B has only the second communication section 22 out of the first communication section 21 and the second communication section 22, and does not communicate with the control device 10 but communicates with the first alarm device 2A. They differ in what they do. All of the five alarm devices 2 also have a function of communicating with the control device 10, and each alarm device 2 may be set as a master device or a slave device by switching with a dip switch etc. In this case, the slave device The alarm device 2 set to 1 may not use the first communication unit 21.

The notification section E1 includes an operating light 24 and a sound section 25. The notification section E1 has a function of notifying the occurrence of a fire.

The acoustic section 25 outputs sound (sound waves). When the control unit 20 determines that a fire has occurred, the sound unit 25 outputs an alarm sound to notify the occurrence of a fire. The acoustic section 25 includes a speaker that converts electrical signals into sound, an acoustic circuit, and the like. The sound section 25 outputs an alarm sound (for example, a "beep" sound). The alarm sound may include, for example, an audio message such as "There's a fire. There's a fire." Further, when the control unit 20 determines that it is time for replacement, a failure, or a dead battery, etc., the sound unit 25 outputs a sound (notification sound) for notifying the occurrence. The sound section 25 outputs an alarm sound and a notification sound on a trial basis even during an operation test. The operation test can be performed by pushing an operating button exposed from the housing of the alarm device 2 or by pulling a pull string led out from the housing. If the operation button is pressed during the alarm, the output of the alarm sound will stop.

The operating light 24 includes a red LED (Light Emitting Diode) 240 as a light source, a lighting circuit, and the like. Note that the color of the light source of the operating light 24 is not particularly limited, and may be other than red. The operating light 24 is off during normal times (when monitoring a fire). When the control unit 20 determines that a fire has occurred, the operating light 24 starts blinking (or lighting) at the same time as the alarm sound starts, and stops when the alarm sound stops issuing. The light emitted from the operating light 24 is guided to the outside of the housing of the alarm device 2 via a translucent operation button. A person (for example, a resident) inside the facility 200 can know that the alarm 2 is activated (detecting a fire) by visually recognizing the red activation blinking over the operation button. When the control unit 20 determines that it is time for replacement, a failure, or a dead battery, the operating light 24 blinks to notify the resident of the occurrence. The operation test of the operating light 24, like the sound part 25, can be performed by pushing the operation button or pulling the drawstring.

(2.3) Control device The control device 10 (control system 1) is a HEMS controller installed in the facility 200 as described above. The control device 10 can communicate with a plurality of electrical devices provided in the facility 200 by wire or wirelessly. The plurality of electrical devices may include, for example, a lighting control device, a shutter control device, an air conditioner, an electric lock control device, a water heater, a smart television, and the like. Here, among the plurality of electrical devices, a shutter control device, an electric lock control device, and a lighting control device correspond to the external device 3. Hereinafter, the shutter control device may be referred to as a first external device 31, the electric lock control device may be referred to as a second external device 32, and the lighting control device may be referred to as a third external device 33.

The control device 10 also performs wireless communication with the first alarm device 2A, which is a base device. The control device 10 can also communicate with the four second alarm devices 2B via the first alarm device 2A. Furthermore, the control device 10 can also communicate with a plurality of external devices 3, information terminals 4, and an external server 5 installed outside the facility 200.

The configuration of the control device 10 will be specifically described below. As shown in FIG. 1, the control device 10 includes a control section C1, a display section D1, a communication section 14, a storage section 15, and the like.

The control unit C1 includes, for example, a computer system. A computer system mainly includes one or more processors and one or more memories as hardware. The functions of the control unit C1 are realized by one or more processors executing programs recorded in one or more memories of the computer system. The program is pre-recorded in one or more memories of the computer system. Note that the program may be provided through a telecommunications line, or may be provided by being recorded on a non-temporary recording medium readable by a computer system, such as a memory card, an optical disk, or a hard disk drive.

The display unit D1 is a thin display device such as a liquid crystal display or an organic EL (Electroluminescence) display. The display section D1 may display device information acquired from each external device 3 and alarm device 2 under the control of the control section C1. The display section D1 may display the device information accumulated in the storage section 15 in a graph form. The device information may include information regarding the operating status and power consumption of the device. It is assumed that the display unit D1 is a touch panel type display device. The display unit D1 receives operation input from the user by, for example, touching the screen of the display unit D1.

The communication unit 14 includes a first communication interface for communicating with the first alarm device 2A. As described above, the first communication interface performs wireless communication with the first alarm device 2A using radio waves in the 920 MHz band. The control unit C1 acquires various information from the first alarm device 2A through the first communication interface.

Furthermore, the communication unit 14 includes a second communication interface that is connected to the network NT1 (see FIG. 2: for example, an Internet line) via a router or the like within the facility 200. The second communication interface communicates with the information terminal 4 and the external server 5 via the network NT1. The information terminal 4 is a smartphone, a tablet terminal, or the like owned by a user (for example, a resident) of the facility 200. In this embodiment, the information terminal 4 is assumed to be a smartphone. Dedicated application software that enables communication with the control device 10 is installed in the information terminal 4. The external server 5 may be a server managed by a security company or the like, or a server managed by the house maker or construction company of the facility 200. The external server 5 may be composed of one server device or may be composed of a plurality of server devices.

Furthermore, the communication unit 14 includes a third communication interface for communicating with a plurality of external devices 3. The third communication interface may communicate with the external device 3 via, for example, a LAN cable, or, like the first communication interface, may communicate wirelessly with the external device 3 using radio waves in the 920 MHz band. You may do so.

The storage unit 15 is configured of a device selected from ROM (Read Only Memory), RAM (Random Access Memory), EEPROM (Electrically Erasable Programmable Read Only Memory), and the like. The storage unit 15 may be a memory of the control unit C1. Further, at least a portion of various information stored in the storage unit 15 described below may be stored in the memory of the control unit C1.

The storage unit 15 stores identifiers (identification information such as IP addresses) of each of the plurality of external devices 3 and the plurality of alarm devices 2. In addition to this, the storage unit 15 stores information regarding the information terminal 4, external server 5, etc. (eg, IP address, email address, telephone number, etc.).

(2.4) Route information Here, the control unit C1 of the control device 10 (control system 1) includes an acquisition unit 11, an output processing unit 12, and a setting unit 13, as shown in FIG. . That is, the control unit C1 has a function as an acquisition unit 11, an output processing unit 12, and a setting unit 13. In other words, the control system 1 includes an acquisition section 11 , an output processing section 12 , and a setting section 13 .

The acquisition unit 11 acquires occurrence information regarding the occurrence of a fire (disaster) that requires evacuation from the facility 200 . Specifically, the acquisition unit 11 acquires, as occurrence information, information indicating a detection result that a fire has occurred from the first alarm device 2A via the first communication interface of the communication unit 14.

The output processing unit 12 generates route information regarding the evacuation route R1 in the facility 200 using the acquisition of the occurrence information as a trigger, and performs output according to the route information.

First, "generation of route information" will be explained. In this embodiment, the output processing unit 12 generates route information based on installation information regarding the installation positions of one or more (here, five) alarm devices 2 (detectors). The storage unit 15 stores installation information in advance. Installation information can be registered by operating the user interface. The "user interface" referred to in the present disclosure corresponds to any one of the touch panel type display section D1, the operation buttons attached to the side of the display section D1, and the information terminal 4, but is not particularly limited. Furthermore, the storage unit 15 stores in advance image information for outputting the floor plan of the facility 200 as an image on the display unit D1. The image information is not limited to a floor plan (plan view) of the facility 200, but may be image information regarding a three-dimensional view of the facility 200. The image information may be downloaded from an external server 5 managed by a house maker of the facility 200 or the like.

A user (resident, installer of the control device 10 or alarm device 2, etc.) can install the alarm device 2 by touching a predetermined area while viewing the image of the floor plan of the facility 200 displayed on the display section D1. It may also be possible to register the location. The user may also be able to register the management area A0 while viewing the image of the floor plan of the facility 200 displayed on the display section D1. Based on the user's operation input, the control unit C1 stores information on a one-to-one correspondence between the five alarm devices 2 and the five management areas A0 in the storage unit 15 as installation information.

In this embodiment, the output processing unit 12 outputs an alarm that detects the occurrence of a fire (disaster) among one or more (here, five) alarm devices 2 (detectors) based on the occurrence information and the installation information. Identify the installation position of device 2 (detector). Furthermore, the output processing unit 12 determines that the specified installation position is the location where a fire (disaster) has occurred, and generates route information based on the location.

In this embodiment, the occurrence information includes identification information of the alarm device 2 (that is, the interlocking source) located at the location of the fire, in addition to information indicating the detection result that a fire has occurred. In other words, the first alarm device 2A also transmits to the control device 10 the identification information of the interlocking source alarm device 2 that detected the fire. The output processing unit 12 refers to the installation information in the storage unit 15 and specifies in which management area A0 the alarm device 2 that is the link source is installed. When the output processing unit 12 specifies the relevant management area A0, it determines that the management area A0 is the location where the fire occurred, and generates route information based on the location where the fire occurred. Specifically, the output processing unit 12 selects an evacuation route R1 that avoids the location of the fire, or an evacuation route R1 that leads to the exit B0 (see FIG. 3) that is farthest from the location of the fire. Generate information. Here, candidates for the exit B0 correspond to the entrance L2, the back exit L3, and the window L4. That is, the output processing unit 12 determines an evacuation exit from a plurality of (three in this case) exits B0 in the facility 200 based on the location of the fire (disaster) occurrence, and generates route information based on the location of the evacuation exit.

Further, in the present embodiment, the output processing unit 12 generates route information based on pattern information regarding an evacuation route R1 when evacuation is performed using each of the plurality of management areas A0 as a starting point P1 (see FIG. 3). The storage unit 15 stores pattern information in advance. Pattern information can be registered by operating the user interface. The user may be able to register pattern information by touching a predetermined area while viewing the image of the floor plan of the facility 200 displayed on the display section D1. Note that FIGS. 3 and 4 show examples of images of the floor plan of the facility 200 that may be displayed on the display unit D1, the information terminal 4, or the like.

For example, a candidate evacuation route R1 for evacuation starting from the second management area A2 (bedroom) P1 may include a first route R11, a second route R12, and a third route R13, as shown in FIG. The first route R11 is a route from the starting point P1 to the first management area A1 to the fourth management area A4 to the entrance L2. The second route R12 is a route from the starting point P1 to the first management area A1 to the back door L3. The third route R13 is a route from the starting point P1 to the window L4. The control unit C1 is capable of registering information regarding the first route R11, the second route R12, and the third route R13 as pattern information for the second management area A2 (bedroom) by operation input from the user. Similarly, the control unit C1 can also register pattern information for other management areas A0. The pattern information may be automatically generated by the control unit C1 in addition to being registered by an operation input from the user. The control unit C1 may automatically generate pattern information based on the arrangement relationship between the management area A0 and the exit B0 (entrance door L2, back door L3, and window L4).

In addition, when a person exists in any one of the plurality of (here, five) management areas A0, the output processing unit 12 outputs route information regarding the evacuation route R1 with the management area A0 as the starting point P1. generate. Specifically, when a fire actually occurs, the output processing unit 12 determines a starting point P1 from which people (for example, residents) in the facility 200 start evacuation. The output processing unit 12 determines the presence or absence of a person in each management area A0 based on at least one of the following first information and second information.

The first information is information including detection results by one or more human sensors that are installed in a plurality of management areas A0 of the facility 200 and detect infrared rays emitted from people. For example, if the output processing unit 12 receives a detection signal indicating the presence of a person from a certain human sensor, it determines that there is a person in the management area A0 where the human sensor is installed, and The area A0 is set as the starting point P1. Note that instead of the human sensor, an imaging device such as a camera may be installed, and a person may be detected from the video captured by the imaging device.

The second information is information regarding the operating status of a plurality of external devices 3 (electrical devices) installed in a plurality of management areas A0 of the facility 200. The second information may be information regarding power consumption of the external device 3. For example, if the output processing unit 12 receives a signal indicating that a certain air conditioner is in operation from the controller of the air conditioner, it determines that a person is present in the management area A0 where the air conditioner is installed. , the management area A0 is set as the starting point P1.

In short, the output processing unit 12 of this embodiment determines the location of the fire occurrence based on the occurrence information and the installation information, and furthermore, if a person is present in the facility 200, the output processing unit 12 determines the location of the fire outbreak from the management area A0 where the person is present as the starting point P1. Set to . Then, the output processing unit 12 selects an optimal evacuation route R1 corresponding to the exit B0 that avoids (or is farthest from) the fire occurrence location from among the pattern information corresponding to the starting point P1. However, the configuration of the output processing unit 12 described above is just an example, and determining the location of a fire is not an essential configuration. If a fire occurs, route information regarding one fixed evacuation route R1 may be generated regardless of the location of the fire. Furthermore, setting the starting point P1, determining the presence or absence of a person, and selecting the optimal evacuation route R1 are not essential configurations. Route information regarding a plurality of fixed evacuation routes R1 may be generated.

Note that the output processing unit 12 may further generate the route information based on at least environmental information regarding the environment around the outside of the facility 200. In this case, the storage unit 15 stores environmental information in advance. The environment information may be downloaded from the external server 5. The environmental information may include map information regarding roads around the outside of the facility 200, nearby facilities (houses, parks, commercial facilities, stations, etc.), street lights, and the like. The output processing unit 12 assigns priorities to the plurality of exits B0 based on the environmental information. For example, a high priority is assigned to an exit B0 facing a relatively wide road or an exit B0 facing a road with streetlights. On the other hand, a low priority is assigned to an exit B0 facing a relatively narrow road or an exit B0 facing a road that is a dead end. When there are multiple evacuation exit candidates, the output processing unit 12 may determine exit B0, which is set to have a high priority, as the evacuation exit. The priority of each exit B0 may be settable by an input operation from the user.

Next, "execution of output according to route information" will be explained. Here, as an example, the output processing unit 12 executes three outputs: the first output, the second output, and the third output, but it may execute only one of the outputs.

The first output includes sending out a control signal for controlling the external device 3. That is, the output processing unit 12 sends out a control signal for controlling at least one external device 3 in the facility 200 to perform output according to the route information. The external device 3 is a device other than the alarm device 2 that detects the occurrence of a fire (disaster) in the facility 200. The output processing unit 12 includes one or more first external devices 31 (shutter control devices), one or more second external devices 32 (electric lock control devices), and a plurality of third external devices 33 (multiple lighting control devices). sends control signals to control the device). The control device 10 transmits a control signal from the communication unit 14 to the external device 3 to be controlled. In the following, it is assumed that the number of first external devices 31 is one and the number of second external devices 32 is two, but these numbers are not particularly limited.

The first external device 31 controls an electric window shutter installed outside the window L4 of the second management area A2 (bedroom). The first external device 31 is installed, for example, on the wall of the second management area A2. The first external device 31 performs wireless communication (wired communication may be used) with the electric window shutter, and transmits a drive signal to open and close the electric window shutter. When the first external device 31 receives the control signal from the control device 10, it transmits a drive signal to the electric window shutter to cause it to perform an operation (for example, an opening operation) according to the control signal.

The two second external devices 32 control the electric lock of the door of the entrance L2 and the electric lock of the door of the back door L3, respectively. One of the second external devices 32 is installed, for example, on the wall of the fourth management area A4 (corridor), and the other second external device 32 is installed on the wall of the first management area A1 (kitchen), etc. . Each second external device 32 performs wired communication (wireless communication is also possible) with the corresponding electric lock, and transmits a drive signal to lock or unlock the electric lock. When each second external device 32 receives a control signal from the control device 10, it transmits a drive signal to the corresponding electric lock to cause it to perform an operation (for example, an unlocking operation) according to the control signal.

The plurality of third external devices 33 are installed on the walls of the first management area A1 to the fifth management area A5, respectively. Each third external device 33 performs wireless communication (wired communication may be used) with the lighting equipment installed on the ceiling surface of the corresponding management area A0, and transmits a signal to turn on, dim, or turn off the lighting equipment. . When each third external device 33 receives a control signal from the control device 10, it sends a signal to the corresponding lighting fixture to perform an operation according to the control signal (for example, full lighting with a dimming rate of 100%). Send.

The second output includes display of route information on the display section D1. That is, the display section D1 displays route information. The output processing unit 12 causes the display unit D1 to display the route information to execute output according to the route information. Specifically, the output processing unit 12 causes the display unit D1 to present route information together with an image of the floor plan of the facility 200. As shown in FIG. 4, the route information may be presented so that the evacuation route R1 can be seen by an arrow H1 superimposed on the floor plan image, or one or more management areas corresponding to the evacuation route R1. The image areas of A0 and exit B0 may be displayed blinking. In the example of FIG. 4, the exit B0 (back exit L3 and window L4) determined as the evacuation exit is displayed blinking. It is desirable that the display section D1 displays the management area A0 corresponding to the starting point P1 so that it can be distinguished from other management areas A0 (in the example of FIG. 4, the second management area A2, which is the starting point P1, is displayed with dot hatching). ). It is desirable that the display section D1 displays the location of the fire so that it can be seen. The display unit D1 may display a message such as "Please exit to the hallway and evacuate from the entrance" in text as the route information.

The second output may further include output of an audio message. The output processing unit 12 may output a voice message specifying the evacuation route R1 from a speaker installed in the control device 10 or the like.

The second output may include displaying the route information on the display unit of the information terminal 4 carried by the resident. The output processing unit 12 transmits the route information from the communication unit 14 to the information terminal 4, and displays the evacuation route R1 so that the evacuation route R1 can be seen by the arrow H1 superimposed on the floor plan image, similar to the presentation on the display unit D1. Alternatively, the information may be displayed on the display section of the information terminal 4. Further, the second output may include displaying route information on a display unit of a television receiver (smart television) that can be connected to the Internet.

The third output includes sending route information to the external server 5 as information provision. The output processing unit 12 transmits route information from the communication unit 14 to the external server 5. Specifically, for example, the control device 10 notifies the external server 5 that a fire has occurred in the facility 200, and also notifies the external server 5 of what evacuation route R1 has been selected by the control device 10. On the external server 5 side, data analysis and the like for the evacuation route R1 selected by the control device 10 can be performed.

By the way, there may be cases where residents of the facility 200 do not want all of the first to third outputs described above to be executed. Specifically, there may be cases where it is not desired to send a control signal to a certain external device 3. Furthermore, there may be cases where the resident does not want route information to be displayed on the information terminal 4 owned by a child in the family.

Therefore, the setting unit 13 of the control unit C1 of this embodiment sets the above-mentioned first to third outputs to be enabled or disabled. That is, the setting unit 13 sets whether or not to send a control signal to each external device 3. The setting unit 13 also sets whether or not to display route information on the display unit D1 and the display unit of the information terminal 4. The setting unit 13 also sets whether or not to send route information to the external server 5. The setting unit 13 displays a setting screen on, for example, the display unit D1 (or the display unit of the information terminal 4) via the user interface, and receives input from the user through a touch operation on the display unit D1. Since the control unit C1 includes the setting unit 13 in this way, it is possible to easily set whether or not the external device 3 can be controlled.

In particular, the control device 10 may be configured to receive, via a user interface, an operation input for applying for "being at home" or "absent (going out)." The control device 10 may disable execution of at least the first output by accepting an "absent" request from the resident when the resident goes out. In short, if the alarm 2 detects a fire while the resident is out and the electric door lock is unlocked without permission even though the resident is not inside the facility 200, the security of the facility 200 will be reduced. there is a possibility. In this way, the execution of the first output is disabled by the "absence" request, thereby suppressing the deterioration of the security of the facility 200. The control device 10 activates execution of the first output when the resident returns home and receives an application for "presence."

(2.5) Operation Description The operation of the disaster prevention system 100 will be described below with reference to FIG. 5. In the following, as an example, it is assumed that a fire breaks out in the third management area A3 (living room) while a resident of the facility 200 is sleeping in the second management area A2 (bedroom) at night.

The alarm 2 (second alarm 2B) installed in the third management area A3 detects a fire (step S1). The alarm device 2 emits an alarm sound (step S2), and transmits an alarm signal to the first alarm device 2A, which is the master device (step S3). When the first alarm device 2A receives the alarm signal from the alarm device 2, it also issues an alarm sound, transmits the alarm signal to the other alarm devices 2, and links the issuing of the alarm sounds ( Step S4). Furthermore, the first alarm device 2A transmits a signal including occurrence information to the control device 10 (step S5).

When the control device 10 receives the signal including the occurrence information, it determines from the occurrence information and the installation information that the location of the fire occurrence is the third management area A3 (living room) (step S6). In addition, the control device 10 determines that the resident is present in the second management area A2 from the detection signal received from a human sensor installed in the second management area A2 (bedroom), and A2 is set as the starting point P1 (step S7). Since the fire outbreak location is in the living room relatively close to the entrance L2, the control device 10 selects a first route R11 in which the evacuation exit is set to the entrance L2 in the pattern information corresponding to the starting point P1. Exclude. Here, as an example, the control device 10 selects two routes as the evacuation route R1: a second route R12 in which the evacuation exit is set to the back door L3, and a third route R13 in which the evacuation exit is set to the window L4. (Step S8). The control device 10 generates route information regarding these two evacuation routes R1 (step S9).

Then, the control device 10 executes the first to third outputs according to the route information.

As a first output, the control device 10 selects the external devices 3 existing on these two evacuation routes R1 as control targets among the plurality of external devices 3 in the facility 200, and transmits a control signal (step S10 ). That is, the control device 10 transmits a control signal to the first external device 31 to cause the electric window shutter of the window L4 to open. The control device 10 also transmits a control signal to the second external device 32 on the side of the back door L3 to unlock the electric lock of the door of the back door L3. Furthermore, the control device 10 transmits a control signal to the third external device 33 installed in the first management area A1, the second management area A2, and the back door L3 to turn on the corresponding lighting fixtures. When the external device 3 to be controlled receives the control signal, it executes the corresponding control (step S11).

The control device 10 causes the display unit D1 to display route information as a second output (step S12). Further, the control device 10 transmits a signal including route information from the communication unit 14 to the information terminal 4 as a second output (step S13). When the information terminal 4 receives the signal including the route information, it displays the route information on its own display unit (step S14). The control device 10 notifies the external server 5 of the route information from the communication unit 14 as a third output (step S15).

As described above, in this embodiment, the output processing unit 12 generates route information regarding the evacuation route R1 in the facility 200 using the acquisition of occurrence information as a trigger, and performs output according to the route information. Therefore, it is possible to reduce the time required for evacuation when a fire (disaster) occurs. Further, since the occurrence information is information indicating the fire detection result by the alarm 2, the time required for evacuation can be further shortened. Furthermore, since the route information is generated based on the installation information of the alarm device 2, more reliable route information can be generated. Further, the output processing unit 12 determines an evacuation exit based on the location of the fire outbreak and generates route information based on the location of the evacuation exit, so it is possible to generate more reliable route information.

Furthermore, since the output processing unit 12 generates route information after specifying the location where a fire has occurred, it is possible to reduce the possibility that, for example, evacuees will mistakenly head toward the location where a fire has occurred. Furthermore, the output processing unit 12 generates route information based on pattern information in the case of evacuation using each of the plurality of management areas A0 as the starting point P1, and therefore can generate route information corresponding to the management area A0. In particular, the output processing unit 12 generates route information regarding the evacuation route R1 starting from the management area A0 where people are present as the starting point P1, and therefore can generate more reliable route information. Note that when a plurality of people exist across a plurality of management areas A0, the output processing unit 12 may generate a plurality of evacuation routes R1 with the management area A0 where each person exists as the starting point P1.

For example, during a time period such as at night when residents of the facility 200 are sleeping, the lighting equipment of the facility 200 is likely to be off and the electric lock on the door of the facility 200 is likely to be locked. Similarly, the electric window shutters of facility 200 may also be closed. When a fire actually breaks out and residents evacuate, actions such as searching for wall switches in the dark to turn on lighting equipment, unlocking doors, and opening electric window shutters are difficult during the evacuation period. This can be an action that delays the process. In particular, these actions can significantly delay evacuation time for residents such as children and the elderly. In this respect, in the present embodiment, the output processing unit 12 transmits a control signal to the external device 3 to be controlled as execution of the first output according to the route information. In other words, the output processing unit 12 is configured to control the external device 3 so as to secure the evacuation route R1. Therefore, the time required for evacuation can be further shortened. Since the lighting fixtures on the evacuation route R1 are lit, the resident not only saves the effort of simply operating a wall switch, but also can visually recognize that the light points to the evacuation route R1.

Further, in the present embodiment, the output processing unit 12 displays the route information on the display unit D1 or the display unit of the information terminal 4 as execution of the second output according to the route information. That is, since the route information is visually output, the recognizability of the evacuation route R1 is improved.

(3) Modifications The above embodiment is just one of various embodiments of the present disclosure. The embodiments described above can be modified in various ways depending on the design, etc., as long as the objective of the present disclosure can be achieved. The control system 1 according to the embodiment described above may be embodied in a processing method, a computer program, a non-temporary recording medium on which a computer program is recorded, or the like. The processing method includes an acquisition step and an output processing step. In the acquisition step, occurrence information regarding the occurrence of a disaster that requires evacuation from the facility 200 is acquired. In the output processing step, route information regarding the evacuation route R1 in the facility 200 is generated using the acquisition of the occurrence information as a trigger, and output is executed according to the route information.

Modifications of the above embodiment will be listed below. The modified examples described below can be applied in combination as appropriate. Below, the above embodiment may be referred to as a "basic example".

The control system 1 (control device 10) in the present disclosure includes a computer system. A computer system mainly consists of a processor and a memory as hardware. The functions of the control system 1 in the present disclosure are realized by a processor executing a program recorded in the memory of the computer system. The program may be pre-recorded in the memory of the computer system, may be provided through a telecommunications line, or may be recorded on a non-transitory storage medium readable by the computer system, such as a memory card, optical disc, hard disk drive, etc. may be provided. A processor in a computer system is comprised of one or more electronic circuits including semiconductor integrated circuits (ICs) or large scale integrated circuits (LSIs). The integrated circuits such as IC or LSI referred to herein have different names depending on the degree of integration, and include integrated circuits called system LSI, VLSI (Very Large Scale Integration), or ULSI (Ultra Large Scale Integration). Furthermore, an FPGA (Field-Programmable Gate Array), which is programmed after the LSI is manufactured, or a logic device that can reconfigure the connections inside the LSI or reconfigure the circuit sections inside the LSI, may also be used as a processor. Can be done. The plurality of electronic circuits may be integrated into one chip, or may be provided in a distributed manner over a plurality of chips. A plurality of chips may be integrated into one device, or may be distributed and provided in a plurality of devices. The computer system herein includes a microcontroller having one or more processors and one or more memories. Therefore, the microcontroller is also composed of one or more electronic circuits including semiconductor integrated circuits or large-scale integrated circuits.

Moreover, it is not an essential configuration for the control system 1 and the disaster prevention system 100 that a plurality of functions in the control system 1 and the disaster prevention system 100 are integrated into one housing. The components of the control system 1 and the disaster prevention system 100 may be distributed and provided in a plurality of housings. On the contrary, a plurality of functions in the control system 1 and the disaster prevention system 100 may be integrated into one housing. Furthermore, at least some functions of the control system 1 and the disaster prevention system 100, for example, some functions of the control system 1 and the disaster prevention system 100 may be realized by a cloud (cloud computing) or the like.

In the basic example, the output processing unit 12 determines the management area A0 where a person is present and sets the starting point P1 based on the operating status of the human sensor, the imaging device, or the electrical equipment. However, the output processing unit 12 may set the starting point P1 in response to an operation input from a person (resident) to the user interface. For example, when the control device 10 receives an operation input from a resident to request "sleep" via the user interface, the control device 10 changes the starting point P1 to the second management area A2 (bedroom) in the event of a fire. It may be set automatically.

In the basic example, the output processing unit 12 transmits a control signal to turn on a plurality of lighting fixtures on the evacuation route R1 as execution of the first output. However, the output processing unit 12 may transmit a control signal to turn off a plurality of lighting fixtures as execution of the first output. For example, the output processing unit 12 may transmit a control signal to turn on a plurality of lighting fixtures on the evacuation route R1 and turn off the other lighting fixtures. In addition, the output processing unit 12 may transmit a control signal to cause a plurality of lighting devices on the evacuation route R1 to blink, or may cause the light to be dimmed at a dimming rate of less than 100%, as execution of the first output. A control signal may be sent to. Further, the output processing unit 12 may control a plurality of lighting devices by combining full lighting, dimmed lighting, blinking lighting, and turning off the lights in order to visually recognize the evacuation route R1. For example, the output processing unit 12 may turn on all the lighting fixtures other than the evacuation route R1 and blink the lighting fixtures on the evacuation route R1, or may set the lighting equipment other than the evacuation route R1 to a dimming rate of 50%. The lighting may be dimmed and all of the lighting equipment on the evacuation route R1 may be turned on.

Each alarm device 2 in the basic example may have, for example, a lighting section that outputs illumination light. In this case, the output processing unit 12 executes the first output by instructing the parent to turn on the lighting section of the alarm device 2 on the evacuation route R1 instead of turning on the lighting equipment on the evacuation route R1. The control signal may be transmitted to the first alarm device 2A, which is the alarm device. Based on the received control signal, the first alarm device 2A transmits a signal to turn on the lighting section to the alarm device 2 selected as the control target.

By the way, in the basic example, assuming that the disaster is a fire, all five alarm devices 2 are fire alarm devices. However, as explained in the "(1) Overview" section, the disaster may be gas leakage, generation of CO (carbon monoxide) due to incomplete combustion, or the like. The disaster prevention system 100 may include at least one gas detector as a detector. That is, the plurality of alarm devices 2 in the basic example may include, for example, one or more fire alarms and one or more gas alarms, or all alarm devices 2 may include gas alarms instead of fire alarms. It may also be an alarm.

Hereinafter, a case where the plurality of alarm devices 2 include one or more gas alarm devices will be specifically described. The gas alarm (alarm 2) is installed in the facility 200 to detect the occurrence of gas in the facility 200. The gas to be detected is not particularly limited, and may include flammable gases such as LP (liquefied petroleum) gas, methane, propane, hydrogen, and gasoline, and toxic gases such as CO.

The output processing unit 12 determines an evacuation exit from the plurality of exits B0 in the facility 200 based on the location of the fire (disaster) and the location of the gas (disaster), and generates route information based on the location of the evacuation exit. . In particular, when generating route information, the output processing unit 12 determines the degree of gas danger in the plurality of candidate evacuation routes R1 from the detection results of the gas alarm (which may include information regarding gas concentration). , the evacuation route R1 with the lowest degree of risk may be selected.

Furthermore, in the basic example, it has been explained that the pattern information regarding the evacuation route R1 can be registered in the storage unit 15 by operating the user interface. Here, it may be possible to register pattern information regarding the evacuation route R1 in consideration of the degree of danger of flammable gas, toxic gas, etc. in the storage unit 15.

For example, the user can register the parking lot adjacent to the facility 200 (considering gasoline), the installation location of gas cylinders, etc. in the storage unit 15 while viewing the map image of the facility 200 and its surroundings displayed on the display unit D1. It's okay. When generating the route information, the output processing unit 12 may select an evacuation route R1 that avoids the registered parking lot and gas cylinder installation location. The output processing unit 12 also acquires the detection results of a gas alarm (alarm 2) installed relatively close to the registered parking lot or gas cylinder installation location, and reflects the results in selecting the evacuation route R1. You may let them.

(4) Summary As explained above, the control system (1) according to the first aspect includes an acquisition section (11) and an output processing section (12). The acquisition unit (11) acquires occurrence information regarding the occurrence of a disaster that requires evacuation from the facility (200). The output processing unit (12) generates route information regarding the evacuation route (R1) in the facility (200) using the acquisition of the occurrence information as a trigger, and performs output according to the route information. According to the first aspect, it is possible to reduce the time required for evacuation when a disaster occurs.

Regarding the control system (1) according to the second aspect, in the first aspect, the occurrence information includes one or more detectors (alarms) installed in the facility (200) to detect the occurrence of a disaster in the facility (200). This is information indicating the disaster detection result in device 2). According to the second aspect, the output according to the route information is executed using the acquisition of the disaster detection result at the facility (200) as a trigger, so that the time required for evacuation can be further shortened.

Regarding the control system (1) according to the third aspect, in the second aspect, the output processing unit (12) generates route information based on installation information regarding the installation position of one or more detectors (alarm device 2). generate. According to the third aspect, more reliable route information can be generated.

Regarding the control system (1) according to the fourth aspect, in the third aspect, the output processing unit (12) selects one of the one or more detectors (alarm device 2) based on the occurrence information and the installation information. Identify the installation location of the detector that detected the occurrence of a disaster. Further, the output processing unit (12) determines that the specified installation location is the location where a disaster has occurred, and generates route information based on the location. According to the fourth aspect, since the route information is generated after specifying the location where the disaster has occurred, it is possible to reduce the possibility that, for example, evacuees will head toward the location where the disaster has occurred.

Regarding the control system (1) according to the fifth aspect, in any one of the first to fourth aspects, the facility (200) is divided into a plurality of management areas (A0). The output processing unit (12) generates route information based on pattern information regarding an evacuation route (R1) when evacuating using each of the plurality of management areas (A0) as a starting point (P1). According to the fifth aspect, route information corresponding to the management area (A0) can be generated regardless of which management area (A0) the starting point (P1) for starting evacuation is.

Regarding the control system (1) according to the sixth aspect, in any one of the first to fifth aspects, the output processing unit (12) is configured to control multiple exits ( An evacuation exit is determined from B0) and route information is generated based on the location of the evacuation exit. According to the sixth aspect, more reliable route information can be generated.

Regarding the control system (1) according to the seventh aspect, in any one of the first to sixth aspects, the output processing unit (12) is configured based on at least environmental information regarding the external surrounding environment of the facility (200). to generate route information. According to the seventh aspect, more reliable route information can be generated.

Regarding the control system (1) according to the eighth aspect, in any one of the first to seventh aspects, the facility (200) is divided into a plurality of management areas (A0). When a person exists in any one of the plurality of management areas (A0), the output processing unit (12) generates an evacuation route (with the starting point (P1) from the management area (A0)). Generate route information regarding R1). According to the eighth aspect, more reliable route information can be generated.

Regarding the control system (1) according to the ninth aspect, in any one of the first to eighth aspects, the output processing unit (12) executes output in the facility (200) according to route information. A control signal for controlling at least one external device (3) is sent out. The external device (3) is a device other than the detector (alarm device 2) that detects the occurrence of a disaster in the facility (200). According to the ninth aspect, the time required for evacuation can be further shortened.

Regarding the control system (1) according to the tenth aspect, in the ninth aspect, the output processing unit (12) controls the external device (3) so as to secure the evacuation route (R1). According to the tenth aspect, the time required for evacuation can be further shortened.

In the ninth aspect or the tenth aspect, the control system (1) according to the eleventh aspect includes a setting section (13) that configures whether or not to send a control signal to the external device (3). , further provided. According to the eleventh aspect, it is possible to easily set whether or not to control the external device (3).

The control system (1) according to the twelfth aspect, in any one of the first to eleventh aspects, further includes a display section (D1) that displays route information. The output processing section (12) causes the display section (D1) to display the route information to execute output according to the route information. According to the twelfth aspect, since the route information is visually output, the recognizability of the evacuation route is improved.

A disaster prevention system (100) according to a thirteenth aspect includes the control system (1) according to any one of the first to twelfth aspects and one or more detectors (alarm device 2). One or more detectors are installed in the facility (200) to detect the occurrence of a disaster in the facility (200). The occurrence information is information indicating the detection result of a disaster by one or more detectors. According to the thirteenth aspect, it is possible to provide a disaster prevention system (100) including a control system (1) that can reduce the time required for evacuation when a disaster occurs.

The processing method according to the fourteenth aspect is a processing method of the control system (1). The processing method includes an acquisition step and an output processing step. In the acquisition step, occurrence information regarding the occurrence of a disaster that requires evacuation from the facility (200) is acquired. In the output processing step, route information regarding the evacuation route (R1) in the facility (200) is generated using the acquisition of the occurrence information as a trigger, and output is executed according to the route information. According to the fourteenth aspect, it is possible to provide a processing method that can reduce the time required for evacuation when a disaster occurs.

The program according to the fifteenth aspect is a program for causing one or more processors to execute the processing method according to the fourteenth aspect. According to the fifteenth aspect, it is possible to provide a function that can shorten the time required for evacuation when a disaster occurs.

The configurations according to the second to twelfth aspects are not essential to the control system (1) according to the first aspect, and can be omitted as appropriate.

1 Control System 11 Acquisition Unit 12 Output Processing Unit 13 Setting Unit 2 Alarm (Detector)
3 External equipment 100 Disaster prevention system 200 Facility A0 Management area B0 Exit D1 Display section P1 Starting point R1 Evacuation route

Claims (8)

an acquisition unit that acquires occurrence information regarding the occurrence of a disaster that requires evacuation from the facility;
an output processing unit that generates route information regarding an evacuation route in the facility using the acquisition of the occurrence information as a trigger, and performs output according to the route information to an output destination different from a source from which the occurrence information is acquired; ,
Equipped with
control system. The occurrence information includes information indicating a detection result of the disaster by one or more detectors installed in the facility to detect the occurrence of the disaster in the facility.
A control system according to claim 1. The output processing unit executes output for displaying an evacuation route to an information terminal.
The control system according to claim 1 or 2. The information terminal that communicates with the control system according to claim 3,
a communication unit that communicates with the control system;
a display unit that displays the evacuation route based on information for displaying the evacuation route received by the communication unit;
Equipped with
Information terminal. A processing method for a control system, the method comprising:
an acquisition step of acquiring occurrence information regarding the occurrence of a disaster that requires evacuation from the facility;
an output processing step of generating route information regarding an evacuation route in the facility using the acquisition of the occurrence information as a trigger, and outputting according to the route information to an output destination different from the source from which the occurrence information was acquired; ,
including,
Processing method. A program for causing one or more processors to execute the processing method according to claim 5. A method for controlling an information terminal including a communication section and a display section, the method comprising:
The acquisition of occurrence information regarding the occurrence of a disaster that requires evacuation from a facility is used as a trigger to generate route information regarding an evacuation route in the facility, and the route information is sent to an output destination different from the source from which the occurrence information is acquired, according to the route information. a receiving step of receiving information for displaying the evacuation route outputted by the communication unit;
a display step of displaying the evacuation route on the display unit based on information for displaying the evacuation route received by the communication unit;
including,
Control method. A program for causing one or more processors to execute the control method according to claim 7.

Images