JP2017215625A - Disaster prevention cooperation system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a disaster prevention cooperation system capable of securing a safe evacuation path when a fire takes place through cooperation between an equipment management system comprising a desk-top interface device controlling a work robot, and a fire alarm system so as to let persons who have difficulties in evacuation such as patients, the aged, etc., to move a safe place.SOLUTION: A receiver 14 of a fire alarm system 10 is configured to transmit, when outputting a fire alarm on receiving a fire signal from a fire sensor 18, fire information including a fire place to a desk-top interface device 15 of an equipment management system 12. The desk-top interface device 15 is configured to: display, when receiving the fire information from the receiver 14, a map of facilities where the fire place is indicated on a screen; instruct a cleaning robot 36 to confirm and display a safe area in the facilities on the screen; and set a safe evacuation path based upon the confirmed safe area and then let a guide display device 32 display an evacuation guide direction.SELECTED DRAWING: Figure 1

Description

  TECHNICAL FIELD The present invention relates to a disaster prevention cooperation system that performs evacuation guidance in the event of a fire by linking a fire notification system and a device management system including a desktop interface device that manages and manages a work robot.

  Conventionally, in facilities where many people are enrolled, such as hospitals and facilities for the elderly, receivers for fire alarm systems that monitor fires have been installed in disaster prevention centers and manager rooms in the facility. By receiving a fire signal from a fire detector or transmitter connected to a sensor line drawn out to the warning area from the fire, a fire representative display is made and the main sound is sounded, and it is also drawn from the receiver. The district acoustic device connected to the control line is ringed, and further, interlocking control of the fire door and fire shutter connected to the control line is performed.

  Moreover, as an evacuation guide apparatus installed with a fire alarm system, emergency broadcast equipment is provided in addition to the guide light determined by the Fire Service Act that always lights up and guides evacuation. The emergency broadcasting equipment is linked to the fire alarm system, and in the event of a fire, a simultaneous emergency broadcast including guidance for evacuation guidance is sent from speakers installed in the hallway of the facility to prompt prompt evacuation. .

  On the other hand, in facilities such as hospitals and elderly facilities, cleaning robots that clean the facilities, transport robots that carry equipment necessary for medical and nursing care sites, wheelchair robots that move people with difficulty walking, Work robots such as stretcher robots that carry bedridden elderly people and hospitalized patients have been put into practical use.

  In order to appropriately manage the operation of various work robots used in such facilities, a device management system using a desktop interface device that can be used as a man-machine interface by a plurality of people is conceivable.

  The desktop interface device arranges a large-screen liquid crystal display with a touch panel horizontally like a table (it can also be arranged vertically), and the parties concerned see the screen display by standing around the table screen. A plurality of people can simultaneously perform screen operations (multi-operation).

  The desktop interface device connects a wireless LAN access point to a transmission line drawn out in the facility to construct a wireless LAN communication area in the facility, and is connected to the terminal device mounted on the work robot via a wireless line. Connect and display the operation status of multiple work robots on the desktop interface device, and specify specific work robots as necessary to instruct the control of predetermined work and movement, thereby concentrating the work robots It is possible to manage the operation.

JP 2009-087111 A JP 2012-194787 A

  By the way, when a fire occurs in a hospital or elderly facility, a fire alarm is automatically output from the receiver of the fire alarm system, and disaster prevention managers and personnel in charge of disaster prevention go to the site and confirm the fire. , Fire confirmation operations, reporting to the fire department, trying to extinguish as much as possible, and instructing evacuation guidance using emergency broadcasts. It is necessary to communicate and move inpatients and elderly people who need help from people to safe places.

  In this case, evacuation guidance is performed assuming an evacuation route that can safely evacuate according to the fire location, but the fire detector is installed on the ceiling surface in the facility, and it is due to the hot air flow rising due to the fire Even if the fire detector is activated, the smoke concentration and temperature are detected, and if the smoke stays on the ceiling surface, it may become a safe place to evacuate for a while. Even if the fire detector is not activated, smoke may spread and become a dangerous place.

  For this reason, even if an evacuation route is set in a direction away from the fire place, for example, even if the evacuation route is set, it is not known if it is safe to visit the site. A safe place may be in a dangerous state, and a situation where safe and reliable evacuation guidance according to the situation on the site is difficult is assumed.

  The present invention secures a safe evacuation route in the event of a fire and secures evacuated persons such as hospitalized patients and elderly people by linking a device management system equipped with a desktop interface device that manages work robots and a fire alarm system. It aims at providing the disaster prevention cooperation system which makes it possible to move to a safe place.

(Disaster prevention cooperation system)
The present invention
A fire alarm system that outputs a fire alarm when a fire signal from a fire detector installed in a facility is received by a receiver and outputs a fire information signal including a fire place to the outside;
An equipment management system that has a control device with a display screen and that uses a control device to manage and control one or more work robots that move in a facility and perform a predetermined work in a normal state;
In disaster prevention cooperation system that links
When the receiver outputs a fire alarm, it sends a fire information signal to the control device.
When the control device receives a fire information signal from the receiver, it displays a map of the facility showing the fire location on the display screen, sends a safety confirmation instruction signal to the work robot, and receives the safety information received from the work robot. Based on the confirmation response signal, the safety area in the facility is displayed on the display screen, and a safe evacuation route is set based on the safety area to notify the evacuation guidance.
It is characterized by that.

(Desktop interface device)
The control device is a desktop interface device in which the display screen is a table screen with a touch panel arranged horizontally or vertically.

(Safety check of allocated area)
The work robot moves within the facility and performs predetermined work. When a safety confirmation instruction signal is received from the control device, the work robot moves to a predetermined allocation area to confirm safety and shows the confirmation result. A response signal is transmitted to the control device.

(Safety confirmation of evacuation route by working robot sensor)
The work robot is equipped with a fire sensor that detects at least one of smoke concentration, temperature, and gas concentration due to fire. When a safety confirmation instruction signal is received from the control device, the work robot moves to the detected value of the fire sensor while moving the assigned area. Based on this, the presence or absence of safety is confirmed, and a safety confirmation response signal indicating the confirmation result is transmitted to the control device.

(Work robot camera)
The work robot further includes an imaging unit that images the inside of the facility, and transmits an image captured by the imaging unit to the control device for display.

(Evacuation route setting based on safety area)
The control device sets an evacuation route in a direction passing through the safety area and away from the fire place toward a predetermined evacuation place or a predetermined temporary evacuation place.

(Information on evacuation routes for which safety has been confirmed)
The control device notifies the evacuation guidance by the evacuation route whose safety is confirmed by a display device and / or an audio output device installed in the facility.

(Continuous monitoring of safety areas and countermeasures against changes)
Even after the evacuation route is set, the control device instructs the work robot to check the safety area in the facility. If the safety area changes, a new evacuation route is reset based on the changed safety area. And let them know the evacuation guidance.

(Wireless communication area in the facility)
The control device constructs a wireless communication area in the facility, and transmits and receives signals by connecting to the work robot via a wireless communication line.
(Confirmation by illumination sensor of work robot)
The work robot further has an illuminance sensor that detects ambient brightness, and controls a signal indicating that the illuminance of the current location is reduced when the detected value of the illuminance sensor falls below a predetermined value. Send to device.

(Basic effect)
The present invention outputs a fire alarm when a fire signal from a fire detector installed in a facility is received by a receiver, and outputs a fire information signal including a fire place to the outside, and a display Linked with a device management system that uses a control device to manage and control one or more work robots that have a control device with a screen and move in the facility to perform predetermined tasks in a normal state In the disaster prevention cooperation system, the receiver sends a fire information signal to the control device when a fire alarm is output, and the control device indicates the fire location when receiving the fire information signal from the receiver. The facility map is displayed on the display screen, a safety confirmation instruction signal is transmitted to the work robot, and the safety area in the facility is displayed on the display screen based on the safety confirmation response signal received from the work robot. Since a safe evacuation route is set based on the area to notify the evacuation guidance, in the event of a fire, the work robot moves through the facility to check whether it is safe for the evacuated person, and fire detection Evacuation that requires human help is possible by accurately ascertaining the situation in the facility where the fire is occurring, which cannot be fully grasped by the vessel, and setting and guiding an evacuation route based on the safety area confirmed on-site It makes it possible to evacuate people who are difficult to evacuate, such as inpatients and elderly people who require time and effort.

(Desktop interface device)
In addition, since the control device is a desktop interface device having a table screen with a touch panel arranged horizontally or vertically, the table screen is surrounded by a plurality of relationships while watching the display of the safety confirmation result by the work robot. An operation (multi-operation) for issuing an instruction for evacuation guidance based on the safety area confirmed on site is possible.

(Effects of safety confirmation of allocated area)
In addition, the work robot moves within the facility and performs a predetermined work, and when a safety confirmation instruction signal is received from the control device, the work robot moves in a predetermined allocation area to confirm the safety and shows the confirmation result. Since the safety confirmation response signal is transmitted to the control device, for example, multiple cleaning robots are arranged in the facility, and the routine cleaning work is performed by moving within the individual work area assigned in the facility. When a safety confirmation instruction is received, it is possible to confirm the safety area in the facility efficiently and in a short time by moving within its own work area and confirming safety.

(Effect of safety confirmation by working robot sensor)
The work robot also has a fire sensor that detects at least one of smoke concentration, temperature, and gas concentration due to fire. When a safety confirmation instruction signal is received from the control device, the work robot detects the fire sensor while moving the assigned area. Since the safety confirmation response signal indicating the confirmation result is sent to the control device based on the value, the work robot such as a cleaning robot or transfer robot is at a height that does not exceed the height of the person. For this reason, it detects the smoke concentration, temperature, and gas concentration in the space near the floor sufficiently away from the ceiling surface where the fire detector is installed, and smoke from the fire stays along the ceiling surface. However, if the space on the floor side is safe, it will be confirmed as a safe area and an evacuation route will be set, while the smoke concentration, temperature, Gas concentration Approaches or insurance level, if it does, are excluded from the safety area, reliably preventing possible that the evacuation through an area which is dangerous. In addition, when both the operating state of the fire detector and the fire sensor of the work robot detect safety, it is possible to take a measure that is considered safer.

(Effect of working robot camera)
In addition, the work robot further includes an imaging unit that images the inside of the facility, and the image captured by the imaging unit is transmitted to the control device for display. Is confirmed by a display image of the control device, and safe and appropriate measures such as evacuation guidance based on on-site confirmation are made possible. In addition, if necessary, the work robot is directed to the fire place according to an instruction from the control device, and the status of the fire site can be grasped from the display image, thereby supporting fire fighting activities.

(Effect of setting evacuation route based on safety area)
In addition, since the control device sets the evacuation route in the direction away from the fire place through the safety area toward the predetermined evacuation place or the predetermined temporary evacuation place, the control device is optimal based on the confirmed safety area. An evacuation route is automatically set, and even an inpatient or an elderly person who is difficult to evacuate such as an inpatient or an elderly person who needs time and effort to evacuate can be evacuated safely.

(Effects of notification of evacuation routes whose safety has been confirmed)
Moreover, since the control device is configured to notify the evacuation guidance by the evacuation route whose safety is confirmed by the display device and / or the audio output device installed in the facility, the display device indicates, for example, the evacuation direction by an arrow display, In addition, the voice output device notifies the evacuation direction and the distance to the evacuation place by a voice message, thereby enabling safe and quick evacuation behavior according to the evacuation route set based on the confirmed safety area. .

(Effects of continuous monitoring of safety areas and coping with changes)
The control device also instructs the work robot to check the safety area in the facility even after the evacuation route is set, and when the safety area changes, a new evacuation route is set based on the changed safety area. Even if the fire spreads, it is possible to notify the evacuation guidance by resetting it so that the change in the safety area over time can be detected reliably and the new evacuation route is reset based on the changed safety area. , Enabling safe and quick evacuation behavior.

(Effect of wireless communication area in the facility)
In addition, since the control device constructed a wireless communication area in the facility and connected to the work robot via a wireless communication line to send and receive signals, the work robot moved freely between the facilities and connected to the control device. Establish a communication connection to enable necessary communication.

(Effect of working robot illuminance sensor)
The work robot further has an illuminance sensor that detects ambient brightness, and when the detected value of the illuminance sensor falls below a predetermined value, a signal indicating that the illuminance at the current location is reduced. Is transmitted to the control device, the control device can set the surrounding area as an evacuation difficult area so that it can be distinguished from other areas, and can assist in setting an evacuation route.

Explanatory diagram showing an overview of the disaster prevention cooperation system Explanatory drawing showing the appearance of the desktop interface device Block diagram showing functional configuration of receiver and desktop interface device Block diagram showing the functional configuration of the cleaning robot Explanatory drawing showing detection of smoke density by fire detector and cleaning robot Explanatory drawing which showed the top view of the monitoring object facility displayed on the desktop interface device together with the work area of the cleaning robot Explanatory drawing showing a plan view of the monitored facility displayed on the desktop interface device in the event of a fire, along with the evacuation route Explanatory drawing showing the plan view of the monitored facility displayed on the desktop interface device when the fire spreads, along with the evacuation route Flow chart showing control of receiver Flow chart showing control of desktop interface device Flow chart showing control of cleaning robot

[Outline of Disaster Prevention Cooperation System]
FIG. 1 is an explanatory diagram showing an outline of the disaster prevention cooperation system. As shown in FIG. 1, the disaster prevention cooperation system includes a fire alarm system 10 and a device management system 12.

(Fire alarm system)
As shown in FIG. 1, the fire alarm system 10 includes a receiver 14, and the receiver 14 is installed in a disaster prevention center or a manager room in a target facility such as a hospital or an elderly facility. The receiver 14 is, for example, an R type that can identify a terminal address, and a fire detector 18 and a transmitter 20 are connected to a monitoring transmission line 16a drawn out to a monitoring area in the facility. Terminal equipment such as the district sound device 22, the fire door 24, and the fire shutter 26 is connected to the drawn out control transmission line 16 b.

  The fire detector 18 and the transmitter 20 connected to the transmission line 16a are provided with a relay function and have a unique address. The fire detector 18 detects the smoke concentration or temperature associated with the fire. When the smoke concentration or temperature reaches a predetermined threshold value indicating the fire level, the fire detector 18 determines that a fire has occurred and issues a fire signal. Send to. The transmitter 20 transmits a fire notification signal to the receiver 14 when the push button switch is turned on by a fire notification operation.

  When the receiver 14 receives a fire signal from the fire detector 18 or a fire notification signal from the transmitter 20, the receiver 14 displays a fire representative display and outputs a main acoustic alarm, and a disaster prevention person or the like accompanying this is sent to the site. In response to a fire confirmation operation when a fire is confirmed, the district acoustic device 22 connected to the control transmission line 16b drawn from the receiver 14 is operated to output a district acoustic alarm, and the fire location The interlocking control for controlling the fire door 24 and the fire shutter 26 corresponding to the above to form a fire prevention section is performed.

  In the case where the emergency broadcast facility is provided, the receiver 14 causes emergency broadcast to be performed by interlocking control of the emergency broadcast facility.

(Equipment management system)
As shown in FIG. 1, the device management system 12 includes a desktop interface device 15 that functions as a control device, and performs management control for daily operation of various work robots used in the facility. ing.

  FIG. 2 is an explanatory diagram showing the appearance of the desktop interface device. A table screen 46 is horizontally arranged on a table base 44, and the table screen 46 is constituted by a liquid crystal display with a touch panel.

  The table screen 46 of the desktop interface device 15 displays images necessary for the management and control of work robots normally used in the facility, and receives a fire information signal from the receiver 14 of the fire alarm system 10. In the event of a fire, a facility map 48 showing the fire location 50 is displayed on the table screen 46, and is used for control processing for evacuation guidance using a work robot.

  Referring to FIG. 1 again, a transmission path 28 using a LAN cable or the like is drawn out from the desktop interface device 15 into the facility. A wireless LAN access point 30 is connected to the transmission path 28, and the wireless LAN is connected to the facility. A wireless communication area is formed.

  A staff member or the like working in the facility carries a portable terminal 34. For example, a cleaning robot 36, a transfer robot 38, a stretcher robot 40, and a wheelchair robot 42 are arranged as work robots, and an access point 30 is provided. Is connected to the desktop interface device 15 via the communication to transmit and receive signals.

  A predetermined area in the facility is assigned to the cleaning robot 36 as a work area, and the cleaning work is automatically performed while moving the work area based on a preset cleaning schedule.

  The transfer robot 38 performs an operation of automatically transporting necessary equipment from a storage location or the like based on designation of a transfer destination such as a medical site or a nursing site in a facility by a staff.

  The stretcher robot 40 and the wheelchair robot 42 carry inpatients and elderly people who are difficult to walk, and perform support work to move to the destination in the facility set by the staff with the attendance of the staff.

(Linkage of fire alarm system and equipment management system)
When the receiver 14 of the fire alarm system 10 receives a fire signal or a fire alarm signal and outputs a fire alarm, the receiver 14 transmits a fire information signal including the fire location to the desktop interface device 15 of the equipment management system 12.

  When the desktop interface device 15 of the device management system 12 receives fire information from the receiver 14, as shown in FIG. 2, the desktop interface device 15 displays a facility map 48 showing the fire location 50 on the table screen 46. For example, a safety confirmation instruction signal is transmitted to the cleaning robot 36 used as a work robot in the facility to confirm the safety area in the facility, and the safety confirmation result is displayed in a table by the safety confirmation response signal received from the cleaning robot 36. Displayed on the screen 46, and then, linked control is performed in which a safe evacuation route is set based on the confirmed safety area and evacuation guidance is notified.

[Functional configuration of disaster prevention cooperation system]
FIG. 3 is a block diagram showing functional configurations of the receiver and the desktop interface device.

(Functional configuration of receiver)
As shown in FIG. 3, the receiver 14 includes a reception control unit 52, a transmission unit 54, an alarm unit 56, a display unit 58, an operation unit 60, a transfer unit 62, and a transmission unit 64.

  The reception control unit 52 is configured by a computer circuit having a CPU, a memory, and various input / output ports, and realizes a predetermined reception control function by executing a program. A transmission path 16a is drawn out from the receiver 14 toward a warning area of the facility, and a fire detector 18 and a transmitter 20 are connected.

  The fire detector 18 and the transmitter 20 have a transmission function for bidirectionally transmitting information to and from the receiver 14, and a unique address including the receiver 14 is assigned in advance. For example, when the maximum number of addresses is 256, the number of fire detectors 18 and transmitters 20 that can be connected to one transmission path 16a is 255. In addition, when using the transmitter currently used for the P-type fire alarm system, the transmitter has a function of bidirectionally transmitting information to and from the receiver 14, and the transmitter is transmitted via a repeater set with an address. Is connected.

  In addition, the control transmission line 16b drawn from the receiver 14 has a transmission function for bidirectionally transmitting information to and from the receiver 14 and has an address set such as a fire door 24 and a fire shutter 26. Terminal equipment is connected.

  Downlink signals from the receiver 14 to the fire detector 18 and the transmitter 20 are transmitted in the voltage mode. The voltage mode signal is transmitted as a voltage pulse that changes the voltage of the transmission line 16a between 18 volts and 30 volts, for example.

  In contrast, upstream signals from the fire detector 18 and the transmitter 20 are transmitted in a current mode. In this current mode, a signal current is passed through the transmission line 16a at the timing of bit 1 of the transmission data, and the upstream signal is transmitted to the receiver as a so-called current pulse train. The transmission of downstream signals and upstream signals from the receiver 14 to terminal devices such as the fire door 24 and the fire shutter 26 is the same.

  Taking the fire detector 18 as an example, the reception control by the reception control unit 52 is as follows. During normal monitoring, the receiver 14 transmits a polling command for normal monitoring in which terminal addresses are sequentially specified. When the fire detector 18 receives a polling command that matches its own set address, normal monitoring is performed. Make a response. For this reason, the receiver 14 can detect a failure with the fire detector 18 that has not responded to the polling command as a failure.

  The receiver 14 repeatedly transmits a batch AD conversion command for each polling command transmission period for all terminal addresses. When the fire detector 18 receives the batch A / D conversion command from the receiver 14, the fire detector 18 samples analog detection data such as detected smoke concentration and temperature and compares them with a predetermined fire level.

  When the analog detection data sampled by the fire detector 18 exceeds the fire level, an interrupt signal is transmitted to the receiver 14 at a response timing to the polling command. This interrupt signal sends a signal that is not normally used such that the response bit string is all ones.

  When receiving the interrupt signal from the fire detector 18, the receiver 14 issues a group search command, receives an interrupt response from the group including the fire detector 18 that detects the fire, and determines the group.

  Subsequently, the individual fire detectors 18 included in the determined group are polled in sequence with addresses, and by receiving the analog data fire response, the sensor address of the fire detector 18 that detected the fire is obtained. Recognize and fire alarm action.

  The control of the terminal devices such as the fire door 24 and the fire shutter 26 by the receiver 14 is a normal monitoring polling command in which the terminal addresses of the terminal devices are sequentially specified during normal monitoring. When operating the terminal device, a predetermined control command is transmitted at the timing of the polling command specifying the address, and when the terminal device receives a control command that matches its own set address, the control specified by the control command is performed. Perform the action.

  The alarm unit 56 includes a speaker and outputs various alarm sounds and voice messages. The display unit 58 is provided with a fire representative lamp, a fault representative lamp, a liquid crystal display equipped with a touch panel, and the like. The operation unit 60 is provided with a fire determination switch, an acoustic stop switch, a district acoustic temporary stop switch, and the like. The transfer unit 62 outputs a fire transfer signal to an external device such as an emergency broadcasting facility and interlocks it.

  When the reception control unit 52 receives a fire signal or a fire notification signal and outputs a fire alarm, the transmission unit 64 transmits a fire information signal including a fire place to the desktop interface device 15.

(Functional configuration of desktop interface device)
As shown in FIG. 3, the desktop interface device 15 includes a device control unit 66, a communication unit 68, a transmission unit 70, a liquid crystal display 72, a touch panel 74, a display unit 76, an operation unit 78, and a database 80. The liquid crystal display 72 and the touch panel 74 constitute a table screen 46.

  The device control unit 66 is constituted by a computer circuit having a CPU, a memory, and various input / output ports, and realizes a predetermined control function by executing a program. A transmission path 28 using a LAN cable is drawn from the communication unit 68 toward the inside of the facility, and signals are transmitted / received to / from the access point 30 connected to the transmission path 28 according to, for example, Ethernet (registered trademark).

  The database 80 stores map information of facilities displayed on the screen at the time of a fire and various information displayed on the screen in daily management.

  The apparatus control unit 66 normally selects information about the operation of work robots such as the cleaning robot 36, the transfer robot 38, the stretcher robot 40, and the wheelchair robot 42 used in the facility shown in FIG. The operation status can be confirmed and necessary operations can be instructed.

  In addition, the device control unit 66 can display information on the resident of the facility based on an information signal from an entrance / exit management system provided in the facility at a normal time. It is also possible to provide various notification items and notifications necessary for the performance of the project.

  When the apparatus control unit 66 receives a fire information signal from the receiver 14 via the transmission unit 70, the apparatus control unit 66 displays a map of the facility indicating the fire location on the table screen 46 by driving the liquid crystal display 72. Based on the safety confirmation result by the safety confirmation response signal received from the cleaning robot 36, for example, the safety confirmation instruction signal is transmitted to the cleaning robot 36 that is moving in the facility corresponding to the fire place, and the safety area in the facility is confirmed. Control is performed so as to notify the evacuation guidance by setting a safe evacuation route based on the confirmed safety area displayed on the table screen 46.

  In addition, in the case of a multi-level facility, the device control unit 66 simultaneously displays a map of a directly upper floor with a high risk of fire due to a fire floor map, or displays a map of an arbitrary floor by a selection operation. It is possible.

  In addition, when the safety area in the facility is confirmed by the cleaning robot 36, the device control unit 66 confirms by the cleaning robot 36 toward a predetermined evacuation place such as a staircase or a predetermined temporary evacuation place close to the staircase. Control to set the evacuation route in the direction away from the fire place through the designated safety area.

  Further, the device control unit 66 instructs the guidance display device 32, for example, installed in the facility via the access point 30 shown in FIG. Control for notifying the evacuation route is performed, for example, by displaying an arrow indicating.

  When a voice guidance device is provided together with the guidance display device 32 in the facility, the distance to the evacuation destination is set for an evacuee who passes in front of the voice guidance device according to an instruction from the device control unit 66. You may make it perform control to alert | report by an audio | voice message.

  In addition, even after the safety area in the facility is confirmed by the cleaning robot 36 and the evacuation route is set by the cleaning robot 36, the apparatus control unit 66 instructs the cleaning robot 36 to check the safety area in the facility. Is changed, a new evacuation route is reset based on the changed safety area, and control for notifying evacuation guidance is performed.

  Furthermore, the apparatus control unit 66 can perform control processing in the training mode, and performs control for training the persons concerned in a state where an arbitrary section in the facility is set as a pseudo fire place. The control of the device control unit 66 in this training mode is preferably performed using, for example, a time zone such as nighttime or a holiday, and the cooperation with the fire alarm system is canceled, and the desktop interface device 15 and the operation staff are controlled. For the portable terminal 34 and the cleaning robot 36, a response process for a pseudo-fire is performed.

  In the training mode, the cleaning robot 36 to which a work area close to a pseudo fire place is assigned receives an instruction to confirm the safety of the work area, and initially responds with a confirmation result indicating the safety area. A training procedure that changes in response to the confirmation result indicating the dangerous area is incorporated, and it is possible to construct a training environment in which the safety area in the facility is reduced with time.

(Functional configuration of the cleaning robot)
FIG. 4 is a block diagram showing a functional configuration of the cleaning robot. As shown in FIG. 4, the cleaning robot 36 includes a robot control unit 82, a communication unit 84 to which an antenna 85 is connected, a travel distance sensor 86, a smoke concentration sensor 88, a temperature sensor 90, a gas sensor 92, an operation display unit 94, An audio notification unit 96, an imaging unit 98, a travel drive unit 100, and a cleaning drive unit 102 are provided.

  The communication unit 84 establishes a communication connection via a wireless line with the access point 30 of the wireless LAN installed in the facility, transmits and receives signals, and communicates with the desktop interface device 15 via the access point 30. Send and receive signals.

  The travel distance sensor 86 detects and outputs the travel distance based on the number of rotations of the traveling wheels provided in the cleaning robot 36.

The smoke density sensor 88 detects and outputs the smoke density at the place where the cleaning robot 36 is located. The temperature sensor 90 detects and outputs the temperature of the place where the cleaning robot 36 is located. The gas sensor 92 detects and outputs the gas concentration of CO gas or CO ₂ gas where the cleaning robot 36 is located.

  Here, the height of the cleaning robot 36 is about 60 centimeters, for example, and the smoke concentration sensor 88, the temperature sensor 90, and the gas sensor 92 detect the smoke concentration, temperature, and gas concentration in a space that is about the height of a person. If the detected smoke concentration, temperature, and gas concentration do not exceed a predetermined danger level, the location can be determined as a safe location.

  The smoke concentration sensor 88, the temperature sensor 90, and the gas sensor 92 function as a fire sensor that detects smoke concentration, temperature, and gas concentration due to fire, and it is desirable to detect all of the smoke concentration, temperature, and gas concentration. However, it is only necessary to detect at least one of smoke concentration, temperature, and gas concentration.

  The operation display unit 94 is used to perform various setting operations and start / stop operations necessary for the cleaning operation of the cleaning robot 36. For example, the travel route can be set by causing the cleaning robot 36 to travel within the assigned area by operating the operation display unit 94 or operating the remote control device. Thereafter, when a cleaning instruction operation is performed, or a timer is set. When the set time by management is reached, the cleaning work is automatically performed according to the set travel route. Further, as a cleaning traveling pattern of the cleaning robot 36, a plurality of types of patterns such as spiral swirling and reciprocating zigzag traveling are registered in advance using the operation display of the operation display unit 94, and an appropriate cleaning traveling pattern is selected from the patterns. You may make it select.

  The voice notification unit 96 includes a speaker, and outputs a predetermined caution sound such as a chime sound to call attention during cleaning work. In addition, the voice notification unit 96 can be used as a voice guidance device in the event of a fire.

  The imaging unit 98 is an ITV camera or the like, and, for example, takes an image of the front of the cleaning robot 36 as a moving image in response to an instruction from the desktop interface device 15 and sends an imaging signal to the desktop interface device 15 for display.

  The travel drive unit 100 drives the travel wheels of the cleaning robot 36. The cleaning robot 36 of the present embodiment has drive wheels that can be independently driven to travel, and drives both wheels at the same speed so that the vehicle travels straight and rotates one of the drive wheels. Rotation is performed at. In addition, a contact sensor or the like is provided in the travel drive unit 100 to enable travel drive to turn or retreat when contacting the wall.

  The cleaning drive unit 102 includes a suction device using a fan and a swiveling brush that collects dust, and performs a floor cleaning operation.

  FIG. 5 is an explanatory diagram showing detection of smoke concentration by a fire detector and a cleaning robot. FIG. 5A shows a state in which smoke due to fire is detected by a fire detector and a cleaning robot. B) shows the change over time of the smoke concentration detected by the fire detector and the cleaning robot when smoke stays on the ceiling, and FIG. 5C shows the fire detector when smoke diffuses throughout the space. The time change of the smoke density detected by the cleaning robot is shown.

  As shown in FIG. 5 (A), the fire detector 18 is installed on the ceiling surface in the facility, and smoke that has risen due to the thermal air current of the fire spreads along the ceiling surface, and a smoke layer below the ceiling surface. 106 is formed, and the fire detector 18 issues a fire signal when the smoke density by the smoke layer 106 reaches the fire level or outputs a fire signal.

  The smoke layer 106 on the ceiling surface side falls to the floor surface side due to an increase in the amount of smoke with the passage of time, and eventually the entire place is wrapped in smoke.

  For this reason, only the fire signal from the fire detector 18 determines whether the installation location of the fire detector 18 is a safe place or not depending on the passage of time since the occurrence of the fire. I don't know for sure.

  On the other hand, the cleaning robot 36 is traveling on the floor surface, and when the smoke concentration sensor 88 is mounted on the upper portion of the cleaning robot 36, the smoke concentration in the space close to the floor surface on which the evacuee 108 moves is detected.

  Therefore, as shown in FIG. 5A, at the stage where the smoke layer 106 is formed on the ceiling surface side, as shown in FIG. 5B, the smoke concentration D1 of the fire detector 18 increases with time. The fire detector 18 is activated when the fire level Dth is exceeded, but the smoke concentration d2 by the smoke concentration sensor 88 of the cleaning robot 36 hardly increases over time, and the fire detector 18 Even if it is working, this place will be safe.

  On the other hand, when smoke spreads over the entire space, as shown in FIG. 5C, the smoke density D2 by the smoke density sensor 88 of the cleaning robot 36 follows the increase in the smoke density D1 of the fire detector 18. If the smoke density D2 detected by the cleaning robot 36 is high, this place is not a safe place.

  In this embodiment, when the desktop interface device 15 receives a fire information signal from the receiver 14, a safety confirmation instruction signal is transmitted to the cleaning robot 36 to confirm the safety of the work area. By receiving a safety confirmation response signal from the cleaning robot 36 indicating the result, the fire detector 18 is operating as shown in FIGS. 5A and 5B, but it is possible to confirm that the area is a safe area. Thus, it is possible to set and guide an optimum evacuation route based on the safety area in the facility.

  In addition, the transport robot 38, the stretcher robot 40, and the wheelchair robot 42 shown in FIG. 1 are also working robots that can travel freely in the facility by being provided with a travel drive unit, like the cleaning robot 36. Since the transport robot 38 used for transporting goods in the facility is close in size to the cleaning robot 36, the transport robot 38 includes a communication unit 84, a smoke concentration sensor 88, a temperature sensor 90, a gas sensor 92, and a voice. By additionally providing the notification unit 96 and the imaging unit 98, it can be used as a work robot for confirming the safety area in the facility when a fire occurs.

[Disaster prevention cooperation processing by desktop interface device]
FIG. 6 is an explanatory diagram showing a plan view of the facility to be monitored displayed on the desktop interface device together with the work area of the cleaning robot.

  As shown in FIG. 6, in the normal state, a facility map 48 showing the facilities in plan view is displayed on the table screen 46 of the desktop interface device 15. The facility in FIG. 6 is an example of an inpatient ward of a hospital. Hospital rooms shown on the upper and lower sides are arranged around a staff station, and a lounge is arranged near the center of the hospital room. In addition, an elevator (EL) room and a staircase are arranged on the left and right sides of the staff station.

  The facility map 48 displayed on the table screen 46 is divided into four work areas A1 to A4 on the left, right, top, and bottom for the corridors and lounges that are common areas, and each of the work areas A1 to A4 is cleaned. Robots 36-1 to 36-4 are assigned to perform cleaning work automatically while traveling in the work areas A 1 to A 4.

  FIG. 7 is an explanatory diagram showing a plan view of a monitored facility displayed on the desktop interface device together with an evacuation route when a fire occurs.

  As shown in FIG. 7, when the desktop interface device 15 receives the fire information signal from the receiver 14, the table interface 46 displays a facility map 48 indicating the fire target area on the table screen 46. In this example, the desktop interface device 15 is shown in the lower left corner of the facility map 48. A hospital room is displayed as a fire place 110, and a fire alarm 18 is output from the receiver 14 by operating the fire sensor 18 installed in the hospital room. If necessary, a map of the floor directly above the fire floor or the selected floor is displayed.

  Further, the receiver 14 responds to a fire confirmation operation based on a fire site confirmation by a manager or the like, and releases the latches of the fire doors 24a and 24b provided in the corridor near the fire place 110 as shown in FIG. In addition, the entrance of the staircase near the fire place and the fire shutters 26a and 26b at the entrance of the elevator room are closed, and this situation is displayed on the facility map 48 by a thick broken line.

  The desktop interface device 15 transmits a fire information signal to the portable terminal 34 carried by the staff working in the facility in accordance with the display of the facility map 48 showing the fire place 110 based on the fire information. The same facility map 48 as the table screen 46 of No. 7 is displayed, and the coping action is started according to the procedure acquired in the daily evacuation drill.

  In addition, the desktop interface device 15 sends a safety confirmation instruction signal to the cleaning robots 36-1 to 36-4 disposed in the facility where the fire has occurred to instruct the safety confirmation of its own work areas A 1 to A 4. To do.

  The cleaning robots 36-1 to 36-4 that have received the safety confirmation instruction signal from the desktop interface device 15 stop the previous cleaning work and move, for example, smoke while moving the work areas A 1 to A 4 according to a predetermined traveling pattern. If the smoke concentration is detected by the concentration sensor 88 and the predetermined danger level has not been reached, a safety confirmation response signal indicating that it is a safe area is transmitted to the desktop interface device 15, and if the predetermined danger level has been reached. Transmits a safety confirmation response signal indicating the danger area to the desktop interface device 15.

  The desktop interface device 15 receives the safety confirmation response signals of the work areas A1 to A4 by the cleaning robots 36-1 to 36-4, and the fire door 24 near the fire place 110, as shown in FIG. The work area A2 confirmed by the cleaning robot 36-2 partitioned by the fire shutter 26 is displayed as the danger area 116, and the work area A1 confirmed by the other cleaning robots 36-1, 36-3, 36-4. , A3 and A4 indicate that they are safe areas. In addition, it is desirable to display the danger area and the safety area in different colors as necessary.

  Subsequently, the desktop interface device 15 is based on the safety areas A1, A3, and A4, and passes through the safety areas A1, A3, and A4 with the staircase shown at the right end away from the fire place 110 serving as an evacuation place as an evacuation destination. The evacuation route 114 indicated by the thick arrow heading to the evacuation site while being away from the location 110 is set and displayed, and an evacuation guidance instruction signal is transmitted to the guidance display device 32 installed in the facility based on the setting of the evacuation route 114. Then, an arrow indicating the evacuation direction is displayed and guided.

  The signals indicating the safety area and the evacuation route 114 displayed on the desktop interface device 15 are sequentially transmitted to and displayed on the portable terminal 32 carried by the staff, and are displayed by the staff corresponding to the setting of the safe evacuation route 114. It is possible to quickly and appropriately carry the inpatient to the evacuation site.

  Further, when the evacuation route is set in the direction indicated by the arrow away from the fire place for the danger area 116 close to the fire place 110 and an inpatient remains in the danger area 116, the desktop interface device 15 is operated. An evacuation guidance instruction signal from the dangerous area 116 is transmitted to the portable terminal 34 of the staff and displayed, and the hospitalized patient can be quickly taken out from the dangerous area 116 by a nearby staff.

  FIG. 8 is an explanatory view showing a plan view of a monitored facility displayed on the desktop interface device together with an evacuation route when a fire spreads.

  As shown in FIG. 8, if the fire shown in FIG. 7 has spread to the adjacent hospital room as time passes, the fire detector 18 installed in the hospital room where the fire has expanded operates to generate a fire signal. Then, the receiver 14 receives the second fire signal, displays a new fire area, and transmits a fire information signal including the expanded fire place to the desktop interface device 15. Moreover, the receiver 14 performs control which newly closes the fire door 24c in the work area A1 of the cleaning robot 36-1 with expansion of a fire.

  For this reason, as shown in FIG. 8, the desktop interface device 15 enlarges and displays the fire place 110 to the adjacent hospital room, and makes it possible to grasp the progress of the fire. In addition, the cleaning robots 36-1 to 36-4 installed in the facility continue working area A 1 after receiving the safety confirmation instruction signal from the desktop interface device 15 and reporting the result by the safety confirmation response signal. Safety is confirmed while moving ~ A4.

  For this reason, as the fire spreads, smoke from the fire place 110 flows into the work area A1 of the cleaning robot 36-1, which has been a safe area so far. For example, the smoke concentration in the work area A1 has reached a dangerous level. When detected by the cleaning robot 36-1, it is transmitted to the desktop interface device 15 that the work area A1 has become a dangerous area by a safety confirmation response signal, and the desktop interface device 15 has been in the previous work area A2. The area 116 is switched to the display expanded to the work area A1, whereby the facility staff recognizes that the safety area has become the work areas A3 and A4 of the cleaning robots 36-3 and 36-4.

  Here, the work area A1 of the cleaning robot 36-1 is partitioned by closing the fire door 24c, and the cleaning robot 36-1 confirms the safety on the left side of the work area A1 near the fire place partitioned by the fire door 24c. Judged to be dangerous. Therefore, the right side of the work area A1 partitioned by the fire door 24c can be dealt with by giving a confirmation instruction to the cleaning robot 36-3 assigned to the adjacent work area A3.

  When the safety area changes in accordance with the expansion of the fire in this way, the desktop interface device 15 creates a new evacuation route indicated by a thick arrow on the right side of the work area A1 that is the changed safety area and the work areas A3 and A4. 114, the arrow indicating the evacuation direction is displayed on the guidance display device 32 installed in the facility, and at the same time, the facility indicating the evacuation route 114 reset on the portable terminal 34 carried by the staff The map 48 is sent and displayed, and it is possible to carry out the work of carrying inpatients etc. to a safe evacuation place along the reset evacuation route 114.

[Control action of disaster prevention cooperation system]
(Fire detector control operation)
FIG. 9 is a flowchart showing the control of the receiver, which is a control operation by the reception control unit 52 provided in the receiver 14 of FIG.

  As shown in FIG. 9, the reception control unit 52 of the receiver 14 determines whether or not there is a fire reception based on the operation (reporting) of the fire detector 18 or the operation of the transmitter 20 in step S <b> 1. If it determines, it will progress to step S2 and will output a fire alarm.

  When the person in charge of disaster prevention confirms the fire in response to the output of the fire alarm, the fire confirmation operation is performed. Therefore, the fire confirmation operation is determined in step S3, and the fire door 24 and the fire shutter 26 corresponding to the fire place are determined. In addition, the smoke-exhaust interlock control is performed to open the smoke-exhaust damper and discharge the smoke from the fire. In addition, the reception control unit 52 proceeds to step S <b> 5 and transmits a fire information signal including a fire place to the desktop interface device 15.

  Then, it progresses to step S6, the reception control part 52 discriminate | determines the presence or absence of the 2nd or later fire reception, and if the 2nd or later fire reception is discriminated, it progresses to step S7 and the area corresponding to the expanded fire The display and smoke-exhaust-linked control are performed, and a fire information signal including the fire place expanded in step S8 is transmitted to the desktop interface device 15.

  Subsequently, the reception control unit 52 repeats the process from step S6 until the recovery operation is determined in step S9. When the recovery operation performed in response to the fire extinguishing is determined in step S9, the process proceeds to step S10. After restoring the fire reception control up to step S11, a fire recovery signal is transmitted to the desktop interface device 15 in step S11, and the process returns to the determination of fire reception in step S1.

(Control operation of desktop interface device)
FIG. 10 is a flowchart showing the control of the desktop interface device, which is a control operation by the device control unit 66 of the desktop interface device 15 shown in FIG.

  As shown in FIG. 10, the device control unit 66 of the desktop interface device 15 displays predetermined daily display and control in step S21, for example, the status of various work robots arranged in the facility, and the like. The operation management is possible.

  Subsequently, the device control unit 66 determines whether or not a fire information signal is received from the receiver 14 in step S22. If it is determined that the fire information signal is received, the device control unit 66 proceeds to step S23, and the portable terminal carried by the staff A fire mode signal is transmitted to 34 and all the work robots, the staff knows that a fire has occurred, waits for the next instruction, and the work robot stops the daily work and enters a standby state waiting for the next instruction.

  Subsequently, the device control unit 66 displays a map of the facility including the fire place on the table screen 46 in step S24, and transmits a safety confirmation instruction signal to the cleaning robot 36 in the standby state in the facility in step S25. Instruct safety confirmation. Subsequently, when the device control unit 66 determines in step S26 that the safety confirmation response signal indicating the confirmation result from the cleaning robot 36 has been received, the process proceeds to step S27, and the safety area is displayed together with the dangerous area on the map of the table screen 46. At the same time, an evacuation route is set based on the safety area.

  Subsequently, the device control unit 66 transmits an evacuation guidance instruction signal to the guidance display device 32 installed in the facility based on the set evacuation route to display an arrow indicating the evacuation direction, etc. In step S29, an evacuation guidance instruction signal is transmitted to the portable terminal 34 of the staff to instruct evacuation action by the set evacuation route.

  Subsequently, when the apparatus control unit 66 determines reception of a safety confirmation response signal indicating the confirmation result of the new safety area from the cleaning robot 36 in step S30, the apparatus control unit 66 proceeds to step S31 and determines that the safety area has changed. Then, it progresses to step S32, an evacuation route is reset based on the changed safety area, and the process from step S26 is repeated.

  If it is determined in step S31 that there is no change in the safety area, the apparatus control unit 66 proceeds to step S33, and repeats the processing from step S30 until a fire recovery signal is received. In step S31, the fire recovery is performed. If it is determined that the signal has been received, the process proceeds to step S34, the fire response control up to that point is restored, and the routine returns to the daily display control in step S21.

(Control action of cleaning robot)
FIG. 11 is a flowchart showing the control of the cleaning robot, which is a control operation by the robot control unit 82 of the cleaning robot 36 shown in FIG.

  As shown in FIG. 11, the robot controller 82 of the cleaning robot 36 performs automatic cleaning control while traveling in the work area assigned to it according to a predetermined work schedule in step S41, and the step during the automatic cleaning control is performed. If it is determined in S42 that a fire mode signal has been received from the desktop interface device 15, the process proceeds to step S43, where the automatic cleaning control is stopped and a standby state is entered.

  Subsequently, when the robot controller 82 determines that the safety confirmation instruction signal is received from the desktop interface device 15 in step S44, the robot controller 82 proceeds to step S45, and travels in the work area assigned to the robot controller 82 while the smoke concentration, temperature, and gas concentration. In step S46, it is determined whether there is safety in the work area, and a safety confirmation response signal is transmitted to the desktop interface device 15.

  Subsequently, the robot control unit 82 repeats the processing from step S45 until it determines the reception of the fire recovery signal from the desktop interface device 15 in step S47, and when the reception of the fire recovery signal is determined in step S47, Controls such as safety confirmation based on the fire information so far are stopped, and the process returns to step S41 to perform automatic cleaning control of the work area.

[Modification of the present invention]
(Fire alarm system)
In the above embodiment, an R-type fire alarm system that can identify a fire place and a control place by setting a terminal address in a fire detector or the like is taken as an example. However, a fire is detected or a terminal device is controlled on a line basis. It is good also as a P-type fire alarm system.

(Target facility)
In the above embodiment, a hospital or an elderly facility where refugee difficulties are expected is taken as an example, but the present invention is not limited to this. For example, an appropriate facility such as an office building or a commercial facility where many people come and go may be used.

(Evacuation guidance by work robot)
In addition, the work robot may notify the desktop interface device when a evacuating person or a remaining person is detected. Further, evacuation guidance may be performed based on evacuation route information when an evacuee or a residual person is detected or according to a human operation. At this time, when the current position is not on the evacuation route, a route for guiding from the current position to the evacuation route or the safety area may be set from the desktop interface device.

(Illuminance sensor of work robot)
The work robot further has an illuminance sensor that detects ambient brightness, and when the detected value of the illuminance sensor falls below a predetermined value, a signal indicating that the illuminance at the current location is reduced. May be transmitted to the desktop interface device. Since the work robot is equipped with an illuminance sensor, the desktop interface device can be set as an evacuation difficult area even when the illuminance is low, so that it can be distinguished from other areas, such as setting an evacuation route Can be of help.

(Other)
In the above embodiment, the facility is classified according to whether it is a safe area or not, but the safety level may be divided in stages. At that time, when the safety level is displayed on the desktop interface device, the risk level may be displayed using, for example, a contour line by using a color change or the like.

  In the above embodiment, the result of the robot qualitatively determining the situation in the facility is transmitted to the desktop interface device, but various sensor data are transmitted to the desktop interface so that the desktop interface determines the situation in the facility. Anyway.

  Further, instead of the desktop interface device, display and operation may be enabled by using a display device such as a known display device or VR and an operation terminal.

  The present invention includes appropriate modifications that do not impair the objects and advantages thereof, and is not limited by the numerical values shown in the above embodiments.

10: Fire alarm system 12: Equipment management system 14: Receiver 15: Desktop interface devices 16a, 16b, 28: Transmission path 18: Fire detector 20: Transmitter 22: District sound device 24: Fire door 26: Fire shutter 30 : Access point 32: Guidance display device 34: Mobile terminal 36, 36-1 to 36-4: Cleaning robot 38: Transport robot 40: Stretcher robot 42: Wheelchair robot 46: Table screen 48: Facility map 50: Fire place 52 : Reception control unit 54, 64, 70: transmission unit 66: device control unit 68, 84: communication unit 72: liquid crystal display 74: touch panel 80: database 82: robot control unit 86: travel distance sensor 88: smoke concentration sensor 90: Temperature sensor 92: Gas sensor 94: Operation display unit 96: Audio notification unit 98: Imaging unit 100 Traveling drive unit 102: the cleaning driving unit 110: Fire Location 114: evacuation route

Claims (10)

A fire alarm system that outputs a fire alarm when a fire signal from a fire detector installed in a facility is received by a receiver and outputs a fire information signal including a fire place to the outside;
An equipment management system having a control device with a display screen, and using the control device to manage and control one or more work robots that move in the facility and perform predetermined work in a normal state When,
In disaster prevention cooperation system that links
When the receiver outputs the fire alarm, the fire information signal is transmitted to the control device,
The control device, when receiving the fire information signal from the receiver, displays a map of the facility showing the fire location on the display screen and transmits a safety confirmation instruction signal to the work robot. The safety area in the facility is displayed on the display screen based on the safety confirmation response signal received from the work robot, and a safe evacuation route is set based on the safety area to notify the evacuation guidance.
Disaster prevention cooperation system characterized by that.
In the disaster prevention cooperation system according to claim 1,
The control device is a desktop interface device that uses a table screen with a touch panel arranged horizontally or vertically as the display screen.
In the disaster prevention cooperation system according to claim 1,
The work robot moves in the facility and performs the predetermined work, and when the safety confirmation instruction signal is received from the control device, the work robot moves in a predetermined allocation area to confirm and confirm the safety. A disaster prevention cooperation system, wherein the safety confirmation response signal indicating a result is transmitted to the control device.
In the disaster prevention cooperation system according to claim 3,
The work robot includes a fire sensor that detects at least one of smoke concentration, temperature, and gas concentration due to a fire, and when the safety confirmation instruction signal is received from the control device, the fire is performed while moving the allocation area. A disaster prevention cooperation system characterized by confirming the presence or absence of safety based on a detection value of a sensor and transmitting the safety confirmation response signal indicating a confirmation result to the control device.
In the disaster prevention cooperation system according to claim 4,
The work robot further includes an imaging unit that images the inside of the facility, and transmits and displays an image captured by the imaging unit to the control device.
In the disaster prevention cooperation system according to claim 1,
The control apparatus sets the evacuation route in a direction passing through the safety area and away from the fire place toward a predetermined evacuation place or a predetermined temporary evacuation place.
In the disaster prevention cooperation system according to claim 1,
The said control apparatus alert | reports the evacuation guidance by the evacuation route by which the said safety was confirmed by the display apparatus installed in the said facility, or an audio | voice output apparatus, The disaster prevention cooperation system characterized by the above-mentioned.
In the disaster prevention cooperation system according to claim 1,
The control device instructs the work robot to confirm the safety area in the facility even after the evacuation route is set, and when the safety area changes, a new one is created based on the changed safety area. A disaster prevention cooperation system characterized by resetting an evacuation route and notifying evacuation guidance.
In the disaster prevention cooperation system according to claim 1,
The control device constructs a wireless communication area in the facility, connects to the work robot through a wireless communication line, and transmits and receives signals.
In the disaster prevention cooperation system according to claim 3,
The work robot has an illuminance sensor that detects ambient brightness, and when the detection value of the illuminance sensor falls below a predetermined value, a signal indicating that the illuminance of the current location is decreased A disaster prevention cooperation system characterized by transmitting to a control device.

Images