KR20190128327A - Disaster alarm system with evacuation guidance function using laser - Google Patents

Abstract

The present invention relates to a disaster alarming system having an evacuation guidance function using a laser. When various disaster situations including fires in various facilities or the like occur, the disaster situations are quickly detected to output an alarm, and the distressed people inside the facility can evacuate a location of the fire occurrence or toxic gas. Using a laser, the identification is possible even in a situation where the smoke is full, thereby quickly and safely evacuating the people to the outside.

Description

Disaster alarm system with evacuation guidance function using laser}

The present invention relates to an alarm system, and in detail, when various disasters, including fire, occur in various facilities, quickly detects and outputs an alarm, but the distressed persons inside the facility are evacuated from the location of the fire or toxic gas. The present invention relates to a disaster warning system having an evacuation induction function using a laser that enables a user to recognize the smoke in a smoke-filled situation and to evacuate to the outside quickly and safely.

In general, a disaster such as a fire causes a large amount of smoke and soot along with toxic gases that are fatal to the human body, putting the refugees in danger. Particularly, a fire in an indoor space such as a public building or a subway used by a large number of people is half. With the use of enclosed structural features, many people are likely to lead to large casualties.

In order to minimize human accidents in the event of such a disaster, it is most desirable to evacuate to a safe outdoor area as soon as possible. Therefore, an emergency equipment for evacuation is required to guide the direction of emergency exit so as to escape from a dangerous situation in which toxic gas is generated.

The relevant legislation is to equip public places with the appropriate number of emergency equipments, and in particular, in places such as narrow corridors, emergency lights are installed in easy-to-check locations so that escape routes can be easily identified.

However, due to its large area and complex structure, a typical multi-use facility is difficult to identify the location of emergency lights in a disaster situation, and it is difficult for an evacuator to secure an escape route without being familiar with the internal structure because various evacuation routes may exist. There was a problem, especially when the smoke generated by the combustion of the various interior materials are lost in the room full situation and move to a place without a fire direction or emergency exit is in great danger.

In addition, conventionally, only the power failure situation is taken into account, so that the emergency power emits light with relatively low intensity or light through luminous material, so that the devices for guiding the emergency exit often fail to serve as a state full of smoke. An improvement was required.

Patent Publication No. 10-1018583 (2011.02.22)

The present invention was created in order to solve the above problems, an object of the present invention is to quickly detect when a variety of disasters, including fire in various facilities, such as to output a warning while the distress people inside the facility is a fire It is to provide a disaster warning system with a laser-induced evacuation function that enables users to evacuate from the location or toxic gas generated, and to use the laser to identify even in a smoke-filled situation. .

The present invention for the above purpose is a unique identifier is installed for each zone of the facility is designated, the monitoring module unit including a fire detection unit for determining the fire by detecting the flame and smoke; A unique identifier is installed and installed for each area of the facility, the laser oscillating unit emitting a laser beam, the rotating unit rotating the laser oscillating unit in a set direction, and a memory for storing an alarm signal including an image and sound according to the disaster type A display for outputting a video alarm signal, a control unit for providing a call function with a disaster type input and control unit, a speaker for outputting an acoustic alarm signal and guide sound at a set volume, a microphone for receiving an audio signal, An evacuation induction module unit having a plurality of LEDs and having a light emitting unit emitting light in a color and pattern designated by an alarm signal; Collects a database storing the evacuation information including the area information and the structure of the facility and the emergency exit location and the movement route, the detection signal and the type of disaster input through the operation unit Monitoring unit for identifying the type of disaster and location of occurrence, Computing unit for calculating the optimum movement route for each zone through the database analysis corresponding to the identified type of disaster and location, and the type and location and calculation of the identified disaster type A control unit for generating a control signal including a control signal of a rotating unit for each evacuation induction module unit and a video and audio alarm signal and a guidance signal to be output, reflecting the movement path, and transmitting the control signal to each corresponding evacuation induction module unit. A control unit including an alarm transmission unit and a communication unit providing a communication function with the evacuation induction module unit; Characterized in that consists of.

In this case, the monitoring module unit includes a first sensor for detecting the concentration of smoke and gas, and a second sensor for detecting the flow of air, the calculation unit reflects the detection results of the first sensor and the second sensor for each zone It is desirable to calculate a travel route that can minimize the exposure of smoke and gases.

The apparatus may further include a blower for discharging air to the front surface of the laser oscillator, and a sprayer for spraying liquid discharged from the liquid container toward the blower to form a mist.

The laser oscillating unit and the rotating unit may be provided in plural, and the evacuation induction module unit may further include an interlocking unit configured to control the respective laser oscillating unit and the rotating unit to output a moving direction on the mist formed on the front surface in response to an alarm signal. Can be.

The evacuation induction module unit may further include an interlocking unit converting the control signal transmitted through the alarm propagation unit so that the evacuator can check through the terminal possessed by the evacuator and transmitting the Bluetooth signal based on the Bluetooth 4.0 broadcasting system.

Through the present invention, in the place requiring efficient evacuation and rescue facilities due to the length and depth of underground spaces, such as underground shopping malls, subway stations, and the like, as well as large buildings and various public facilities, as well as multi-use facilities that people use a lot. In the event of a disaster, the escape route can be quickly identified, effectively protecting lives.

In addition, even in a situation where the field of view is difficult to secure compared to a conventional device that only prepares for a power failure, the evacuation path can be identified smoothly through laser emission, sound warning, and terminal interlocking. By calculating the optimum movement route can be made quickly and safely evacuation.

In addition, unlike existing emergency lighting and guidance devices, the survivor can easily check through the improved projection performance even in the smoke filled in the evacuation route.

1 is a conceptual diagram of the present invention,
2 is an external view of the evacuation induction module unit according to an embodiment of the present invention,
3 is a block diagram showing a configuration and a connection relationship according to an embodiment of the present invention;
4 is an external view of an evacuation induction module unit according to an embodiment of the present invention;
5 is a block diagram illustrating a configuration and a connection relationship according to an embodiment of the present invention.

Hereinafter, with reference to the accompanying drawings will be described in detail the configuration of a disaster warning system having an evacuation induction function using a laser.

1 is a conceptual diagram of the present invention, Figure 2 is an external view of the evacuation induction module unit according to an embodiment of the present invention, Figure 3 is a block diagram showing the configuration and connection relationship according to an embodiment of the present invention, It is divided into a number of zones and applied to various facilities or buildings having a complicated structure to control signals transmitted from the monitoring module 110 for fire and disaster monitoring connected to wired / wireless when installed in various zones in case of various disasters including fire. Through the unit 140 and evacuation induction module unit 120 to propagate to each area and to provide information for minimizing human injury.

The monitoring module unit 110 is installed for each zone that is a unit for monitoring a fire, each of which is assigned a unique identifier, basically by detecting the flame and smoke to monitor the fire is the most frequent type of disaster Along with the fire detection unit 111 to determine the will include an earthquake detection unit 114 that can cause a large number of lives.

The fire detection unit 111 detects the flame and smoke generated in the area together to ensure accurate fire detection, and in the case of the earthquake detection unit 114 can detect the shaking of facilities or buildings, including commercial seismometers. It is implemented through sensors to detect earthquakes. If necessary, the monitoring module 110 may include various sensors adapted to the detection target so as to detect various disasters such as terrorism.

The evacuation induction module 120 is configured to propagate information for evacuation along with the disaster information to people in the facility or building, and the unique identifier is designated and installed in each area of the facility as in the monitoring module unit 110. The laser oscillation unit 121, the rotating unit 122, the memory 123, the display 124, the operation unit 125, the speaker 126, the microphone 127, and the light emitting unit 128 are provided in detail.

The evacuation induction module 120 may be made in various forms, but it is made of the appearance such as a video phone, smart pad, etc. as shown in FIG. It is installed where possible.

The laser oscillator 121 is a configuration for emitting a laser beam to the front of the evacuation induction module 120, in the present invention basically improves the identification power during disaster by guiding the escape route through the laser beam. Although a single laser beam may indicate the direction, it is preferable to emit the laser beam through a plurality of light emitting laser diodes so that it can be easily identified even in a relatively long distance or in a smoky situation. In particular, it is preferable to use the green laser in the 532 nm wavelength range having excellent visibility among the laser beams, and it is also possible to use a plurality of laser beams to form an arrow-shaped spot or other guide marker for the evacuation direction.

The rotating unit 122 is an electric actuator that rotates the laser oscillating unit 121 in a set direction, and rotates the laser oscillating unit 121 in up, down, left and right directions within a set angle range to guide the direction so that the evacuator can easily determine the escape direction. To help.

The memory 123 stores an alarm signal including an image and a sound according to a disaster type. Disaster type, as mentioned above, can basically be a fire or an earthquake, flooding, depending on the nature of the crime or facilities, such as earthquakes or terrorism. The video and sound for informing such a disaster type are prepared in advance and stored in the memory 123 as an alarm signal, and are basically made by expressing the location of the disaster, the current location, the escape route, and the like as the video and sound.

The display 124 is composed of an LCD or LED panel to output a video alarm signal, can also be used for video phones, etc., equipped with a brightness control function to operate at 25 to 50 Lux brightness in normal operation, but disaster It enhances the brightness at the time of occurrence and outputs the image with brightness of more than 100 Lux so that the video alarm signal can be identified smoothly even in the event of poor visibility due to smoke or dust in case of fire.

The operation unit 125 includes a basic operation command, in particular, a type of directly receiving a disaster type from a user or providing a call function with the control unit 140. The user basically selects a given menu consisting of a button or a touch pad. To allow the operation to take place.

That is, even in a situation in which a disaster such as a fire, earthquake, crime, and the like is not detected by the monitoring module unit 110 as shown in the accompanying drawings, the user can notify the occurrence of a disaster to the control unit 140 by pressing the remote control. Through the call function with the control unit 140 is configured to deliver a disaster situation or rescue signal to the manager.

The speaker 126 outputs an acoustic alarm signal and a guide sound at a set volume to assist in the delivery of disasters and guidance information through sounds in a situation where a user is inconvenient in vision or a situation in which it is difficult to secure a visual field, and a call through the operation unit 125. When the function is implemented, it plays a role of receiving and outputting the voice of the administrator of the control unit 140.

In response to the call function, the microphone 127 is configured to receive a user's sound signal and transmit the same to the control unit 140.

The light emitting unit 128 basically consists of a plurality of LEDs to emit light in a color and pattern designated by an alarm signal, so that the evacuation induction module unit 120 can be easily found and accessed even in the dark or smoke.

Through a series of detailed configurations configured in the evacuation induction module unit 120 can not only solve the problem of the conventional one-dimensional disaster alarm system that simply operated the emergency bell but also easily add to the existing system to promote human safety. Can be.

The control unit 140 is connected to the monitoring module 110 and evacuation induction module 120 and wired and wireless to control the situation, the database 141 and the monitoring unit 142 and the calculation unit 143 ) And the control unit 144, the alarm wave unit 145 and the call unit 146, and may be installed in the form of a separate management server in a remote place, and in some cases, each evacuation induction module unit 120 It may be installed in a form that is included in whole or in part.

The database 141 is a configuration in which the evacuation information including the area information and the structure of the facility, the emergency exit location, and the movement path where the monitoring module unit 110 and the evacuation induction module unit 120 are installed is stored. As mentioned above, as the monitoring module unit 110 and the evacuation induction module unit 120 is given a unique identifier, it is possible to identify and individually install locations of the monitoring module unit 110 and the evacuation induction module unit 120. Communication can be made.

The location of the emergency exit provided in the facilities and the respective locations in each area in the state that the installation position of each monitoring module 110 and evacuation information module unit 120 on the structural information of the entire facility to which the present invention is applied is previously identified for each zone The entire path that can be moved to the emergency exit is pre-arranged in consideration of the number of all cases to build the database 141.

The monitoring unit 142 collects the detection signal of the monitoring module unit 110 and the type of disaster input through the operation unit 125 and identifies the type of disaster and the location of occurrence, and each monitoring module unit 110. And a state of being constantly connected to the evacuation induction module unit 120, collecting and monitoring signals, and detecting a disaster type and occurrence position when a disaster type input is detected through a specific monitoring module unit 110 or an operation unit 125. The monitoring module unit 110 or the evacuation induction module unit 120 that transmits the signal is identified.

The calculator 143 calculates an optimal movement route for each zone through analysis of the database 141 in response to the type of disaster and the location of the disaster identified through the monitoring unit 142. . The optimal movement route is basically based on the shortest distance to the emergency exit, but the algorithm does not analyze the route where there are no risk factors such as flame or smoke on the movement route.

The control unit 144 is a signal for controlling each evacuation induction module unit 120 by reflecting the type of disaster and the location of occurrence detected by the monitoring unit 142 and the movement route calculated by the calculation unit 143. In particular, a control signal for controlling the angle of the rotation unit 122 for each evacuation induction module unit 120 and a control including a video and audio alarm signal and a guide signal to be output through the display and the speaker, respectively. Will generate a signal.

Since the general disaster occurrence location is unchanged for all zones, all types of evacuation induction module 120 are installed in the same manner, and the video and sound for guiding the disaster type and the location of occurrence are the same, but the movement paths are different for each zone. The control signal or guide signal for driving the rotating unit 122 of the induction module unit 120 needs to be generated to reflect the position of each zone.

The alarm propagation unit 145 transmits the control signal generated by the control unit 144 to each of the evacuation induction module unit 120 corresponding to the unique identifier assigned to each evacuation induction module unit 120. The delivery is made, the user can be guided to the movement route for the escape based on the area where they are currently located.

The call unit 146 is configured to operate as a user selects a call function through the operation unit 125. The call function is provided through the microphone 127 and the speaker 126 provided in the evacuation module module 120. And, if the control unit 140 is present with the administrator in the remote location, the user and the administrator of the area can take measures such as being notified of the disaster situation or fostering the movement route. In addition, if necessary, a function of transmitting a guide broadcast to all the remaining evacuation induction module unit 120 via the control unit 140 in the form of voice broadcasting through one evacuation induction module unit 120 may be implemented. .

Through such a series of configurations, evacuees located in each zone receive information about the detected disaster location and provide information and evacuation through the video and audio of the disaster location through the evacuation induction module unit 120 installed in each zone. Movement route guidance can be made for.

Figure 4 is an external view of the evacuation induction module unit according to the second embodiment of the present invention, Figure 5 is a block diagram showing the configuration and connection relations according to the second embodiment of the present invention, the disaster situation based on the configuration of the first embodiment described above In response to the safer evacuation and evacuation induction module unit 120 is provided with an additional configuration for checking. In the following description, in order to prevent the gist of the present invention from being blurred, detailed descriptions of the same functions and configurations as those of the first embodiment will be omitted and the description will be focused on the additional configuration.

In the second embodiment of the present invention, the monitoring module unit 110 includes a first sensor 112 for detecting the concentration with the presence of smoke and gas, and a second sensor 113 for detecting the flow of ambient air. do. This is configured to specifically grasp the situation in which smoke and toxic gases generated by fire, including fire, move from zone to zone in a specific zone after a fire occurs in a specific zone. In addition to measuring the concentration of smoke and gas, the air sensor for each zone is measured by the second sensor 113 made of a wind direction sensor. Do.

In response, the calculation unit 143 reflects the smoke and gas distribution and movement direction for each zone by reflecting the detection results of the first sensor 112 and the second sensor 113 to expose the smoke and gas when the evacuator moves. It is equipped with an algorithm to calculate the movement route to minimize the time required to minimize the suffocation accident.

In addition, even when the smoke is full, even if the brightness of the laser oscillator 121, the display 124, and the light emitting unit 128 is bright, visibility may be greatly reduced, which may cause a situation in which an evacuator cannot easily find it. Of course, it is possible to guide through the sound output through the speaker 126, but even in a situation where the disaster is accompanied by ambient noise, even if it is not possible, it is possible to increase the visibility of the laser through local forced blowing and smoke reduction. The air blowing unit 131 and the spray unit 132 may be provided at the side of the evacuation induction module unit 120.

The blower 131 is provided with a small powerful fan to exhaust the strong air to the front of the laser oscillator 121 to push the soot and widen the visible range of the laser. Preferably, rather than venting air in one direction, it is necessary to add wings to control the flow of air to generate vortices and to widen the range of laser propagation into the smoke.

In addition, the spray unit 132 includes a container 133 in which a liquid such as water is accommodated so as to reduce a part of the soot component, and sprays the liquid discharged from the container 133 toward the blower unit 131 to provide a laser. The soot component forming the mist within the output range is reduced. Although various modifications are possible, the solenoid valve 134 may be installed to open and close the nozzle and the nozzle to the front of the blower 131 in a state in which the inert gas and the liquid are pressurized and filled in the container 133, but the blower may be By opening the solenoid valve 134 during the operation of the 131, the liquid may be naturally sprayed through the internal pressure of the container 133 to form a mist.

In addition, each of the evacuation induction module unit 120 is provided with a plurality of laser oscillation unit 121 and the rotating unit 122 is configured to individually control the laser output angle for each laser oscillation unit 121, the The evacuation induction module 120 continuously controls the respective laser oscillation unit 121 and the rotating unit 122 in response to the alarm signal to output the moving direction on the mist formed on the front surface. Can be added. This can improve the discrimination power by promoting the scattering of the beam through the mist as the angle of the laser beam is continuously converted rather than outputting the laser in a single direction.

In addition, the evacuation induction module unit 120 is the alarm propagation unit 145 so that a terminal possessing a Bluetooth function as a terminal possessed by a user approaches and receives guide information as the terminal approaches the evacuation induction module unit 120. It may further include a beacon unit for converting the control signal transmitted through the refugee to check through the terminal possessed by the Bluetooth 4.0-based broadcasting method.

In order to implement such an additional function, the evacuator must possess a terminal, and it is necessary to activate the Bluetooth function in a state in which an application to which access is granted is installed in advance.

The rights of the present invention are not limited to the embodiments described above, but are defined by the claims, and those skilled in the art can make various modifications and adaptations within the scope of the claims. It is self-evident.

110: monitoring module 111: fire detection unit
112: first sensor 113: second sensor
114: earthquake detection unit 120: evacuation induction module unit
121: laser oscillation unit 122: rotating part
123: memory 124: display
125: control panel 126: speaker
127: microphone 128: light emitting unit
129: linkage 131: blower
132: spraying unit 133: container
134: valve 140: control unit
141: database 142: monitoring unit
143: calculator 144: controller
145: alarm wave unit 146: call unit

Claims (5)

A unique identifier is installed for each zone of the facility to be designated, the monitoring module unit 110 including a fire detection unit 111 to detect the flame and smoke to determine the fire;
A unique identifier is designated and installed according to the area of the facility, the laser oscillator 121 emitting the laser beam, the pivot 122 rotating the laser oscillator 121 in a set direction, and the image and sound according to the disaster type. Memory 123 to store the alarm signal, including a display 124 for outputting the video alarm signal, the operation unit 125 to provide a call function with the disaster type input and control unit 140, and the set volume A speaker 126 for outputting an acoustic alarm signal and guide sound, a microphone 127 for receiving an acoustic signal, and a light emitting unit 128 having a plurality of LEDs to emit light in a color and pattern designated by the alarm signal. Evacuation induction module unit 120 provided;
The database 141 stores the information on the area in which the monitoring module unit 110 and the evacuation induction module unit 120 are installed, the structure of the facility, the location of the emergency exit, and the movement route, and the monitoring module unit 110. The monitoring unit 142 collects a detection signal and a disaster type input through the operation unit 125 and identifies a disaster type and a location, and analyzes the database 141 in response to the identified disaster type and location. A control unit 143 for calculating an optimum movement route for each zone, and a control signal of the rotation unit 122 for each evacuation induction module unit 120 by reflecting the identified disaster type and occurrence location and the calculated movement route; A control unit 144 for generating a control signal including a video and audio alarm signal and a guide signal to be output; an alarm propagation unit 145 for transmitting the control signal to each evacuation induction module unit 120; Evacuation induction module unit 120 and The control unit having a call unit 146 to provide a call function of the; Disaster alarm system having an evacuation guidance function using a laser, characterized in that consisting of.
The method of claim 1,
The monitoring module unit 110 includes a first sensor 112 for detecting the concentration of smoke and gas, and a second sensor 113 for detecting the flow of air,
The calculator 143 calculates a movement path that minimizes exposure of smoke and gas for each zone by reflecting the detection results of the first sensor 112 and the second sensor 113. Disaster alert system with evacuation guidance.
The method of claim 2,
The blower 131 for discharging air to the front of the laser oscillator 121, and the sprayer 132 for forming a mist by spraying the liquid discharged from the liquid container 133 to the blower 131 side further Disaster alarm system having an evacuation guidance function using a laser, characterized in that it comprises.
The method of claim 3,
The laser oscillation unit 121 and the rotating unit 122 is provided with a plurality,
The evacuation induction module unit 120 further includes an interlocking unit 129 configured to control the respective laser oscillation unit 121 and the rotating unit 122 to output a moving direction on the mist formed on the front surface in response to an alarm signal. Disaster alarm system having an evacuation guidance function using a laser, characterized in that.
The method of claim 1,
The evacuation induction module 120 further includes a communication unit for converting the control signal transmitted through the alarm propagation unit 145 so as to be confirmed through the terminal possessed by the evacuator, and transmitting the broadcast signal based on the Bluetooth 4.0-based broadcasting method. Disaster alarm system having an evacuation induction function using a laser.

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