JP5404664B2 - Blinking device, guide light device, and evacuation guidance system - Google Patents

Description

  The present invention relates to an evacuation guidance system for evacuating a person indoors when a disaster occurs.

  In order to evacuate people indoors in the event of a disaster such as a fire, there is a guide light device that indicates an evacuation route.

Utility model registration No. 3050480

Depending on the type of disaster, there are cases where it should be evacuated promptly or where it should be evacuated calmly.
The present invention has been made, for example, in order to solve the above-described problems, and an object thereof is to appropriately guide evacuation according to the type of disaster.

  The flashing device according to the present invention flashes when the earthquake determination unit that determines the occurrence of an earthquake, the fire determination unit that determines the occurrence of a fire, and the fire determination unit determines that a fire has occurred. It is characterized by having a light source unit that is continuously lit when it is not determined that a fire has occurred and the earthquake determination unit determines that an earthquake has occurred.

  According to the blinking device according to the present invention, it is possible to appropriately guide evacuation when a fire occurs and when an earthquake occurs.

1 is a system configuration diagram illustrating an overall configuration of an evacuation guidance system 800 according to Embodiment 1. FIG. FIG. 3 is a perspective view showing an appearance of the guide light device 100 according to the first embodiment. FIG. 3 is a partial normal sectional view showing the structure of the blinking unit 130 in the first embodiment. FIG. 3 is a block configuration diagram showing the configuration of the guide light device 100 according to the first embodiment. FIG. 2 is a block configuration diagram showing a configuration of a control circuit 140 in the first embodiment. FIG. 2 is a block configuration diagram showing a configuration of a guide light circuit 221 in the first embodiment. FIG. 3 is a block configuration diagram illustrating a configuration of a blinking circuit 231 according to the first embodiment. FIG. 6 is a flowchart showing a flow of evacuation guidance processing S510 in the first embodiment. FIG. 6 is a partial normal sectional view showing a structure of a blinking unit 130 in the second embodiment. FIG. 6 is a partial normal sectional view showing a structure of a blinking unit 130 according to Embodiment 3. FIG. 9 is a block configuration diagram illustrating a configuration of a blinking circuit 231 according to Embodiment 3. FIG. 10 is a system configuration diagram illustrating an overall configuration of an evacuation guidance system 800 according to a fourth embodiment. FIG. 10 is a perspective view showing an appearance of a blinking device 101 in a fourth embodiment. FIG. 6 is a block configuration diagram showing a configuration of a blinking device 101 in a fourth embodiment. The flowchart figure which shows the flow of the evacuation guidance process S510 in Embodiment 4. FIG. FIG. 10 is a perspective view showing an appearance of a blinking device 101 in a fifth embodiment. FIG. 10 is a perspective view showing an appearance of a blinking device 101 in a sixth embodiment. FIG. 10 is a block configuration diagram illustrating a configuration of a blinking device 101 according to a sixth embodiment. The flowchart figure which shows the flow of the evacuation guidance process S510 in Embodiment 6. FIG. FIG. 20 is a perspective view illustrating an appearance of a blinking device 101 according to a seventh embodiment. FIG. 9 is a partial normal sectional view showing a structure of a blinking unit 130 according to an eighth embodiment. FIG. 20 is a block configuration diagram illustrating a configuration of a blinking circuit 231 according to an eighth embodiment. FIG. 20 is a schematic diagram showing the movement of the blinking unit 130 in the eighth embodiment. FIG. 10 is a partial normal cross-sectional view showing a structure of a blinking unit 130 according to Embodiment 9.

Embodiment 1 FIG.
The first embodiment will be described with reference to FIGS.

FIG. 1 is a system configuration diagram showing the overall configuration of an evacuation guidance system 800 in this embodiment.
The evacuation guidance system 800 is installed indoors such as in a building and is a system that evacuates people indoors when a fire or an earthquake occurs. The evacuation guidance system 800 includes a power distribution facility 810, a fire alarm facility 820, an emergency broadcast facility 830, a guide light device 100, a power line 891, a fire signal line 892, and an earthquake signal line 893.
The power distribution facility 810 supplies power supplied from a commercial power source or the like to the guide lamp device 100 or the like via a power line 891.
The fire alarm facility 820 (fire detection device) detects the occurrence of a fire. The fire alarm system 820 includes, for example, a smoke detector, a heat detector, a fire alarm, etc., and detects smoke and heat generated by the fire, or detects the occurrence of a fire by the operation of the person who found the fire. To do. When the fire alarm facility 820 detects the occurrence of a fire, it notifies the fire department and the like, and outputs a fire signal. The fire signal line 892 transmits the fire signal output by the fire alarm facility 820 to the guide lamp device 100.
The emergency broadcast facility 830 (earthquake detection device) detects the occurrence of an earthquake. The emergency broadcast facility 830 includes, for example, a vibration sensor, an earthquake early warning reception device, and the like, and detects the occurrence of an earthquake by sensing an earthquake shake or receiving an earthquake early warning transmitted by the Japan Meteorological Agency or the like. When the emergency broadcast facility 830 detects the occurrence of an earthquake, it performs an emergency broadcast and outputs an earthquake signal. The earthquake signal line 893 transmits the earthquake signal output from the emergency broadcast facility 830 to the guide lamp device 100.
The guide light device 100 is installed in an emergency exit or an evacuation route in accordance with the provisions of the Fire Service Law. The guide light device 100 indicates an evacuation route so that a person indoors can evacuate safely.

FIG. 2 is a perspective view showing the appearance of the guide light device 100 in this embodiment.
The guide light device 100 includes a fixture main body 110, a display main body 121, and a blinking unit 130.
The instrument main body 110 has a rectangular parallelepiped box shape and incorporates a guide lamp circuit and the like to be described later. One side of the instrument body 110 is open. The display main body 121 is attached to the instrument main body 110 so as to close the opened surface of the instrument main body 110. The display main body 121 has a symbol surface 122 in the center. On the symbol surface 122, a symbol indicating evacuation guidance determined by the Fire Service Act or the like is printed.
The blinking unit 130 is provided on a surface that is on the lower side when the guide lamp device 100 is installed, among the six surfaces of the fixture body 110.

FIG. 3 is a normal partial cross-sectional view showing the structure of the flashing unit 130 in this embodiment.
The flashing unit 130 includes a xenon lamp 131, a xenon lamp socket 132, an LED 133, a printed wiring board 134, and a cover 135.
The printed wiring board 134 (substrate) is fixed to the instrument main body 110 so that the mounting surface is located on the same surface as the lower surface of the instrument main body 110.
The xenon lamp socket 132 is mounted on the printed wiring board 134 and connects the xenon lamp 131. The xenon lamp 131 (first light source unit) is held by the xenon lamp socket 132 at a position protruding downward from the lower surface of the instrument body 110. Thereby, the xenon lamp 131 emits light in a direction including a substantially horizontal direction. The flashing unit 130 may have a configuration in which the xenon lamp socket 132 is not provided and the xenon lamp 131 is directly connected by soldering or the like.
The xenon lamp 131 blinks in the event of a fire so that the guide light device 100 can be seen even when the field of view is deteriorated due to smoke or the like.
The LED 133 (second light source unit) is mounted on the printed wiring board 134 and is disposed downward on substantially the same surface as the lower surface of the instrument main body 110. A plurality of LEDs 133 are provided so as to surround the xenon lamp 131 held in the xenon lamp socket 132. The LED 133 emits light in a direction including a substantially vertical downward direction. The LED 133 illuminates the floor surface when an earthquake occurs so that it can be safely evacuated even when an object is scattered at the foot of the earthquake. Further, when a fire occurs, the LED 133 blinks together with the xenon lamp 131.
The cover 135 is a transparent cover that covers the xenon lamp 131 and the LED 133.

FIG. 4 is a block configuration diagram showing the configuration of the guide light device 100 in this embodiment.
The guide light device 100 includes a power terminal block 160, a fire signal terminal block 170, an earthquake signal terminal block 180, a guide light unit 220, a blinking unit 230, a control unit 240, and electric wires 191 to 197 connecting them. And have.
The power supply terminal block 160 has electric wire insertion holes 161-164. A power line 891 is inserted and fixed in the electric wire insertion hole 161, and electric power supplied from the power distribution facility 810 is input. Electric wires 191 to 193 are inserted and fixed in the electric wire insertion holes 162 to 164, respectively, and are electrically connected to the power supply line 891.
The fire signal terminal block 170 has wire insertion holes 171 and 172. A fire signal line 892 is inserted and fixed in the wire insertion hole 171, and a fire signal is input from the fire alarm facility 820. An electric wire 194 is inserted and fixed in the electric wire insertion hole 172, and is electrically connected to the fire signal line 892.
The earthquake signal terminal block 180 has wire insertion holes 181 and 182. An earthquake signal line 893 is inserted and fixed in the electric wire insertion hole 181, and an earthquake signal is input from the emergency broadcast facility 830. An electric wire 195 is inserted and fixed in the electric wire insertion hole 182, and is electrically connected to the seismic signal line 893.

The control unit 240 generates a control signal for controlling the guide light unit 220 and the blinking unit 230. The control unit 240 includes a control circuit 140, a power supply terminal 243, a fire input terminal 244, an earthquake input terminal 245, and control output terminals 246 and 247.
The power terminal 243 is electrically connected to the electric wire 193 and inputs power supplied from the power distribution facility 810 via the power terminal block 160. The fire input terminal 244 is electrically connected to the electric wire 194 and inputs the fire signal output from the fire alarm facility 820 via the fire signal terminal block 170. The earthquake input terminal 245 is electrically connected to the electric wire 195 and inputs the earthquake signal output from the emergency broadcast facility 830 via the earthquake signal terminal block 180. The control circuit 140 controls the illuminance control signal for controlling the guide light unit 220 and the flashing control for controlling the flashing unit 230 based on the fire signal input from the fire input terminal 244 and the earthquake signal input from the earthquake input terminal 245. Signal. The control output terminal 246 is electrically connected to the electric wire 196 and outputs the illuminance control signal generated by the control circuit 140. The control output terminal 247 is electrically connected to the electric wire 197 and outputs a blinking control signal generated by the control circuit 140.
In normal times, the control circuit 140 operates with power input from the power supply terminal 243. Moreover, the control unit 240 has a battery (not shown), and the control circuit 140 operates with the power stored in the battery at the time of a power failure. The battery is charged with electric power input from the power supply terminal 243 during normal times.
The control unit 240 may be configured to exist independently from the guide lamp device 100. In that case, only one control unit 240 needs to exist in the evacuation guidance system 800, and the guide lamp device 100 receives the illuminance control signal and the blink control signal output from the control unit 240 instead of the fire signal and the earthquake signal. input.

The guide light unit 220 includes a display unit 120, a guide light circuit 221, a battery 222, a power supply terminal 223, and a control input terminal 224.
The display unit 120 includes a display main body 121, a display panel 123, a light guide plate 124, and a display light source unit 125. The display light source unit 125 includes an LED 126, a printed wiring board 127, and a lamp holder 128. The LED 126 is mounted on a printed wiring board 127 (substrate). The lamp holder 128 holds the printed wiring board 127 and fixes the held printed wiring board 127 to the display main body 121. The display panel 123 has a symbol surface 122 on which a design for evacuation guidance is printed on the surface, and emits light in response to light emitted from the LED 126. The light guide plate 124 guides the light emitted by the LEDs 126 so that the symbol surface 122 of the display panel 123 is evenly illuminated.
The power terminal 223 is electrically connected to the electric wire 191 and inputs power supplied from the power distribution facility 810 via the power terminal block 160. The control input terminal 224 is electrically connected to the electric wire 196 and inputs an illuminance control signal output from the control unit 240.
The guide light circuit 221 charges the battery 222 with power input from the power supply terminal 223 and supplies power to the LED 126 in the normal state. In addition, the guide light circuit 221 turns on the LED 126 with the power from the battery 222 during a power failure. The guide light circuit 221 changes the brightness at which the LED 126 is lit based on an illuminance control signal or the like input from the control input terminal 224.

The blinking unit 230 includes a blinking unit 130, a blinking circuit 231, a battery 232, a power supply terminal 233, a control input terminal 234, and a guidance sound output unit 235.
The power supply terminal 233 is electrically connected to the electric wire 192 and inputs power supplied from the power distribution facility 810 via the power supply terminal block 160. The control input terminal 234 is electrically connected to the electric wire 197 and inputs the blinking output signal output from the control unit 240.
The blinking circuit 231 charges the battery 232 with power input from the power supply terminal 233 and supplies power to the xenon lamp 131 and the LED 133 in the normal state. The blinking circuit 231 lights the xenon lamp 131 and the LED 133 with power from the battery 232 at the time of a power failure. The blinking circuit 231 blinks the xenon lamp 131 and the LED 133 or continuously lights them based on the blink control signal input from the control input terminal 234.
In addition, the guide sound output unit 235 outputs a guide sound such as a voice in accordance with the lighting of the xenon lamp 131 and the LED 133.

  In addition, the structure which shares one battery with the guide light unit 220 and the blinking unit 230 may be sufficient. Moreover, the structure which supplies the electric power which operates the control circuit 140 at the time of a power failure from the battery 222 or the battery 232 instead of providing a battery in the control unit 240 may be sufficient.

FIG. 5 is a block configuration diagram showing the configuration of the control circuit 140 in this embodiment.
The control circuit 140 is configured by, for example, a logic circuit. The control circuit 140 includes a fire determination unit 144, an earthquake determination unit 145, and a control signal generation unit 146.
The fire determination unit 144 determines whether or not a fire has occurred based on the fire signal input from the fire input terminal 244. The fire determination unit 144 determines that a fire has occurred when the fire input terminal 244 inputs a fire signal. Thereafter, even if the fire input terminal 244 stops inputting a fire signal, the fire signal line 892 may be disconnected due to a fire, and the fire signal may not reach the guide lamp device 100. For this reason, the fire determination unit 144 continues to determine that a fire has occurred until a reset process such as pressing a reset button (not shown) is performed. In other cases, the fire determination unit 144 determines that no fire has occurred.
The earthquake determination unit 145 determines whether an earthquake has occurred based on the earthquake signal input from the earthquake input terminal 245. The earthquake determination unit 145 determines that an earthquake has occurred when the earthquake input terminal 245 inputs an earthquake signal. Thereafter, even if the earthquake input terminal 245 stops inputting an earthquake signal, the earthquake signal line 893 may be disconnected due to an earthquake, and the earthquake signal may not reach the guide lamp device 100. For this reason, the earthquake determination unit 145 continues to determine that an earthquake has occurred until a reset process such as pressing a reset button (not shown) is performed. In other cases, the earthquake determination unit 145 determines that an earthquake has not occurred.
The control signal generation unit 146 generates a control signal based on the determination results of the fire determination unit 144 and the earthquake determination unit 145.
When the fire determination unit 144 determines that a fire has occurred, the control signal generation unit 146 generates a control signal representing the time of the fire occurrence.
When the fire determination unit 144 determines that a fire has not occurred and the earthquake determination unit 145 determines that an earthquake has occurred, the control signal generation unit 146 generates a control signal representing the occurrence of the earthquake.
When the fire determination unit 144 determines that no fire has occurred, and the earthquake determination unit 145 determines that no earthquake has occurred, the control signal generation unit 146 generates a control signal that represents a normal time.
The control output terminal 246 outputs the control signal generated by the control signal generation unit 146 as an illuminance control signal. The control signal representing the normal time is interpreted as an illuminance control signal indicating 100% illuminance. The control signal indicating the time of fire occurrence is interpreted as an illuminance control signal indicating 70% illuminance. The control signal indicating the occurrence of an earthquake is interpreted as an illuminance control signal indicating an illuminance of 50%.
The control output terminal 247 outputs the control signal generated by the control signal generation unit 146 as a blinking control signal. The control signal indicating the normal time is interpreted as a blinking control signal instructing turning off. The control signal representing the time of fire occurrence is interpreted as a blinking control signal for instructing blinking lighting. A control signal representing the occurrence of an earthquake is interpreted as a blinking control signal instructing continuous lighting.

FIG. 6 is a block configuration diagram showing the configuration of the guide light circuit 221 in this embodiment.
The guide light circuit 221 includes a power supply circuit 251, a power failure determination unit 252, a power supply switching circuit 253, a charge / discharge circuit 254, an illuminance setting circuit 255, and a lighting circuit 256.
The power supply circuit 251 converts the power input from the power supply terminal 223 into DC power suitable for charging the battery 222.
The power failure determination unit 252 determines whether there is a power failure. For example, based on the potential of the power supply terminal 223, the power failure determination unit 252 determines whether or not power is being input from the power supply terminal 223.
The power supply switching circuit 253 switches the power supply of the lighting circuit 256 based on the determination result of the power failure determination unit 252. When the power failure determination unit 252 determines that there is no power failure, the power supply switching circuit 253 supplies the DC power converted by the power supply circuit 251 to the charge / discharge circuit 254 and the lighting circuit 256. When the power failure determination unit 252 determines that there is a power failure, the power supply switching circuit 253 supplies the power supplied from the charge / discharge circuit 254 to the lighting circuit 256.
The charge / discharge circuit 254 charges / discharges the battery 222 based on the determination result of the power failure determination unit 252. When the power failure determination unit 252 determines that there is no power failure, the charge / discharge circuit 254 charges the battery 222 with the power supplied from the power supply switching circuit 253. When the power failure determination unit 252 determines that there is a power failure, the charge / discharge circuit 254 supplies the power stored in the battery 222 to the power supply switching circuit 253.
The illuminance setting circuit 255 sets the brightness for turning on the LED 126 based on the determination result of the power failure determination unit 252 and the illuminance control signal input by the control input terminal 224. When the power failure determination unit 252 determines that there is no power failure, the illuminance setting circuit 255 sets the brightness to light the LED 126 to 100% regardless of the content of the illuminance control signal. When the power failure determination unit 252 determines that there is a power failure, the illuminance setting circuit 255 sets the brightness at which the LED 126 is lit to 100%, 70%, or 50% according to the instruction of the illuminance control signal.
The lighting circuit 256 converts the power supplied from the power supply switching circuit 253 into power for lighting the LED 126 with the brightness set by the illuminance setting circuit 255, and supplies the power to the LED 126.

FIG. 7 is a block configuration diagram showing the configuration of the blinking circuit 231 in this embodiment.
The blinking circuit 231 includes a power supply circuit 261, a power failure determination unit 262, a power supply switching circuit 263, a charge / discharge circuit 264, a blinking control circuit 265, a lighting circuit 266, and a lighting circuit 267.
The power supply circuit 261 converts the power input from the power supply terminal 233 into power suitable for charging the battery 232.
The power failure determination unit 262 determines whether there is a power failure. The power failure determination unit 262 determines whether or not power is being input from the power supply terminal 233 based on, for example, the potential of the power supply terminal 233, and determines that it is a power failure when it is determined that the power is not input.
The power supply switching circuit 263 switches the power supply of the lighting circuits 266 and 267 based on the determination result of the power failure determination unit 262. When the power failure determination unit 262 determines that there is no power failure, the power supply switching circuit 263 supplies the DC power converted by the power supply circuit 261 to the charge / discharge circuit 264 and the lighting circuits 266 and 267. When the power failure determination unit 262 determines that there is a power failure, the power supply switching circuit 263 supplies the power supplied from the charge / discharge circuit 264 to the lighting circuits 266 and 267.
The charge / discharge circuit 264 charges / discharges the battery 232 based on the determination result of the power failure determination unit 262. When the power failure determination unit 262 determines that there is no power failure, the charge / discharge circuit 264 charges the battery 232 with the power supplied from the power supply switching circuit 263. When the power failure determination unit 262 determines that there is a power failure, the charge / discharge circuit 264 supplies the power stored in the battery 232 to the power supply switching circuit 263.
The lighting circuit 266 converts the power supplied from the power supply switching circuit 263 into power that causes the xenon lamp 131 to blink and supplies the power to the xenon lamp 131.
The lighting circuit 267 converts the power supplied from the power supply switching circuit 263 into power that causes the LED 133 to blink or continuously light and supply the power to the LED 133.
The blinking control circuit 265 controls the operation of the lighting circuits 266 and 267 based on the blinking control signal input from the control input terminal 234. When the blinking control signal instructs to turn off, the blinking control circuit 265 stops the operation of the lighting circuits 266 and 267. When the blinking control signal instructs blinking lighting, the blinking control circuit 265 causes the lighting circuit 266 to perform blinking lighting operation and causes the lighting circuit 267 to perform blinking lighting operation. When the blinking control signal instructs continuous lighting, the blinking control circuit 265 stops the operation of the lighting circuit 266 and causes the lighting circuit 267 to perform continuous lighting operation.

  The guide sound output unit 235 outputs a guide sound based on the blinking control signal input from the control input terminal 234. When the blinking control signal instructs to turn off, the guide sound output unit 235 does not output the guide sound. When the blinking control signal instructs blinking lighting, the guidance sound output unit 235 outputs a guidance sound that informs the occurrence of a fire (for example, a voice saying “Fire has occurred. Please evacuate immediately”). When the blinking control signal instructs continuous lighting, the guidance sound output unit 235 outputs a guidance sound for notifying the occurrence of an earthquake (for example, a voice saying “An earthquake has occurred. Please evacuate without panic”).

FIG. 8 is a flowchart showing the flow of the evacuation guidance process S510 in this embodiment.
The evacuation guidance process S510 includes an earthquake determination process S511, a fire determination process S512, S522, a power failure determination process S513, a display lighting process S514, S515, S524, a blinking process S516, a floor surface irradiation process S526, and a guide sound. Output steps S517 and S527 and reset determination steps S518 and S528 are included.
In the earthquake determination step S511, the earthquake determination unit 145 determines whether or not an earthquake has occurred. When it determines with an earthquake occurrence, the earthquake determination part 145 advances a process to fire determination process S522. When it determines with it not being an earthquake occurrence, the earthquake determination part 145 advances a process to fire determination process S512.
In the fire determination step S512, the fire determination unit 144 determines whether or not a fire has occurred. If it is determined that a fire has occurred, the fire determination unit 144 advances the process to the power failure determination step S513. If it is determined that no fire has occurred, the fire determination unit 144 returns the process to the earthquake determination step S511.
In the power failure determination step S513, the power failure determination unit 252 determines whether there is a power failure. When it determines with a power failure, the power failure determination part 252 advances a process to display lighting process S515. When it determines with it not being a power failure, the power failure determination part 252 advances a process to display lighting process S514.
In the display lighting step S514, the lighting circuit 256 lights the LED 126 with 100% brightness. The lighting circuit 256 advances the process to the blinking step S516.
In the display lighting step S515, the lighting circuit 256 lights the LED 126 with 70% brightness.
In the blinking step S516, the lighting circuit 266 blinks the xenon lamp 131. The lighting circuit 267 blinks the LED 133.
In the guide sound output step S517, the guide sound output unit 235 outputs a guide sound when a fire occurs.
In the reset determination step S518, the fire determination unit 144 determines whether or not it has been reset. When it determines with having been reset, the fire determination part 144 returns a process to earthquake determination process S511. When it determines with not having been reset, the fire determination part 144 returns a process to the power failure determination process S513.
In the fire determination step S522, the fire determination unit 144 determines whether or not a fire has occurred. If it is determined that a fire has occurred, the fire determination unit 144 advances the process to the power failure determination step S513. If it is determined that no fire has occurred, the fire determination unit 144 proceeds to the display lighting step S524.
In the display lighting step S524, the lighting circuit 256 lights the LED 126 with 50% brightness.
In the floor surface irradiation step S526, the lighting circuit 266 turns off the xenon lamp 131. The lighting circuit 267 lights up the LED 133 continuously.
In the guide sound output step S527, the guide sound output unit 235 outputs a guide sound when an earthquake occurs.
In the reset determination step S528, the earthquake determination unit 145 determines whether or not it has been reset. When it determines with having been reset, the earthquake determination part 145 returns a process to earthquake determination process S511. When it determines with not having been reset, the earthquake determination part 145 returns a process to fire determination process S522.

When a fire occurs, the field of view deteriorates due to smoke or the like. Therefore, by blinking the xenon lamp 131 and the LED 133, the guide lamp device 100 can be easily found and evacuated quickly. In addition, when an earthquake occurs, it may take time to evacuate due to scattering of objects on the floor. Therefore, by continuously lighting the LED 133, it becomes easier to grasp the surrounding situation and evacuate safely.
Also, if a fire and an earthquake occur at the same time, it prompts evacuation by performing the same operation as at the time of the fire.

  Since the xenon lamp 131 (first light source unit) emits light toward a wide range including a direction that is substantially horizontal when the guide lamp device 100 is installed, the guide lamp device 100 can be easily found even from a distance. Moreover, since LED133 (2nd light source part) radiates | emits light toward the comparatively narrow range containing the direction used as a substantially perpendicular downward direction at the time of installation of the guide light apparatus 100, it illuminates a floor surface with sufficient brightness. Can do.

  When a power failure has not occurred, the LED 126 of the display light source unit 125 is lit with 100% brightness (first illuminance), so that it is easy to find the guide lamp device 100 even from a distance. When a power outage occurs in the event of a fire, the LED 126 is turned on with 70% brightness (second illuminance), and is stored in the battery 222 for a time (for example, 20 to 60 minutes) determined by the Fire Service Act. It can be lit with power. In addition, when a power failure occurs at the time of the earthquake, the LED 126 is lit at 50% brightness (third illuminance), so a time longer than the time determined by the Fire Service Act (for example, 40 minutes to 120 minutes), Can be lit. When a fire breaks out, it is necessary to evacuate quickly before the fire starts. On the other hand, when an earthquake occurs, it is necessary to evacuate carefully, such as scattering of objects, which may take time. For this reason, the display panel 123 is illuminated for a longer time when an earthquake occurs than when a fire occurs. In addition, when a fire occurs, the visibility may be deteriorated by smoke. Therefore, even if the display panel 123 is made to shine darker than when a fire occurs, the visibility does not deteriorate.

  In addition, since the occurrence of an earthquake is determined based on the earthquake early warning, evacuation guidance can be started before actual shaking occurs.

  Furthermore, since the guidance sound is used for evacuation guidance, it is possible to appeal not only to the visual sense but also to the auditory sense, and the evacuation guidance can be surely performed.

Embodiment 2. FIG.
The second embodiment will be described with reference to FIG.
In addition, about the part which is common in Embodiment 1, the same code | symbol is attached | subjected and description is abbreviate | omitted.

FIG. 9 is a partial normal sectional view showing the structure of the flashing unit 130 in this embodiment.
The cover 135 covers the xenon lamp 131 but does not cover the LED 133. The LED 133 directly emits light in a direction including a substantially vertical downward direction from an opening hole 111 provided in the lower surface of the instrument main body 110.

  As described above, the LED 133 may be provided outside the cover 135.

  Further, the cover 135 may be a diffusion cover instead of a transparent cover.

Embodiment 3 FIG.
The third embodiment will be described with reference to FIGS.
In addition, about the part which is common in Embodiment 1, the same code | symbol is attached | subjected and description is abbreviate | omitted.

FIG. 10 is a normal partial cross-sectional view showing the structure of the flashing unit 130 in this embodiment.
The blinking unit 130 does not have the xenon lamp 131 described in the first embodiment.

FIG. 11 is a block diagram showing the configuration of the blinking circuit 231 in this embodiment.
The blinking circuit 231 does not include the lighting circuit 266 described in Embodiment 1.

  If the luminance of the LED 133 is sufficiently high, the same effect as in the first embodiment can be obtained even in the configuration without the xenon lamp 131. In addition, the structure which raises the brightness | luminance as a whole by increasing the number of LED133 may be sufficient.

Embodiment 4 FIG.
The fourth embodiment will be described with reference to FIGS.
In addition, about the part which is common in Embodiment 1, the same code | symbol is attached | subjected and description is abbreviate | omitted.

FIG. 12 is a system configuration diagram showing the overall configuration of the evacuation guidance system 800 in this embodiment.
The evacuation guidance system 800 further includes a flashing device 101 in addition to the configuration described in the first embodiment.
The flashing device 101 is obtained by removing the guide light unit 220 from the guide light device 100. The blinking device 101 is installed between the guide light device 100 and the guide light device 100 at a place where the installation distance of the guide light device 100 is separated, for example. Alternatively, the blinking device 101 may be installed near a guide lamp device that does not have the blinking unit 230.

FIG. 13 is a perspective view showing the appearance of the flashing device 101 in this embodiment.
The blinking device 101 is installed, for example, embedded in a wall surface. The blinking device 101 includes an instrument main body 110, a blinking unit 130, and a speaker 151.
The flashing unit 130 is provided not on the lower surface of the instrument body 110 but on the side surface of the instrument body 110. The LED 133 is, for example, a side emitter type LED, and emits light in a substantially vertical downward direction.
The speaker 151 is a part of the guide sound output unit 235 and emits a guide sound.

FIG. 14 is a block configuration diagram showing the configuration of the blinking device 101 in this embodiment.
The blinking device 101 does not have the guide light unit 220 in the guide light device 100 described in the first embodiment. Accordingly, the blinking device 101 does not have the electric wire 191 that connects the power terminal block 160 and the guide light unit 220 or the electric wire 196 that connects the control unit 240 and the guide light unit 220.

FIG. 15 is a flowchart showing the flow of the evacuation guidance process S510 in this embodiment.
The evacuation guidance process S510 does not include the power failure determination process S513 and the display lighting processes S514, S515, and S524 among the processes described in the first embodiment.
When it is determined that a fire has occurred in the fire determination steps S512 and S522, and when it is determined that the reset has not been reset in the reset determination step S518, the fire determination unit 144 advances the process to the blinking step S516.
Moreover, when it determines with it not being a fire outbreak in fire determination process S522, the fire determination part 144 advances a process to floor surface irradiation process S526.

  In this way, by installing the flashing device 101 in a place where the installation interval of the guide light device 100 is far away or near the guide light device that does not have the flashing unit 230, the floor area that can be irradiated when an earthquake occurs Spread and can be evacuated safely.

  Note that the blinking unit 130 is not the configuration described in the first embodiment, but may be a configuration in which the LED 133 is provided outside the cover 135 as described in the second embodiment, or the third embodiment. As described above, a configuration without the xenon lamp 131 may be used.

Embodiment 5 FIG.
The fifth embodiment will be described with reference to FIG.
In addition, about the part which is common in Embodiment 4, the same code | symbol is attached | subjected and description is abbreviate | omitted.

FIG. 16 is a perspective view showing the external appearance of the blinking device 101 in this embodiment.
The flashing device 101 is installed, for example, embedded in a ceiling surface. The blinking device 101 includes an instrument main body 110, a blinking unit 130, and a speaker 151.
The flashing unit 130 and the speaker 151 are provided on the lower surface of the instrument main body 110.

  Even if the blinking device 101 has such a configuration, the same effects as those of the fourth embodiment can be obtained.

  The evacuation guidance system 800 may have a configuration in which the blinking device 101 described in the fourth embodiment and the blinking device 101 described in this embodiment are mixed.

Embodiment 6 FIG.
The sixth embodiment will be described with reference to FIGS.
In addition, about the part which is common in Embodiment 4, the same code | symbol is attached | subjected and description is abbreviate | omitted.

FIG. 17 is a perspective view showing the appearance of the blinking device 101 in this embodiment.
The blinking device 101 does not have the speaker 151, but includes the instrument main body 110 and the blinking unit 130.

FIG. 18 is a block configuration diagram showing the configuration of the blinking device 101 in this embodiment.
The blinking device 101 has a configuration in which the guide sound output unit 235 is removed from the blinking device 101 described in the fourth embodiment.

FIG. 19 is a flowchart showing a flow of the evacuation guidance process S510 in this embodiment.
The evacuation guidance process S510 does not include the guidance sound output steps S517 and S527 among the steps described in the fourth embodiment.
After the blinking step S516, the blinking circuit 231 advances the processing to the reset determination step S518.
After the floor surface irradiation step S526, the blinking circuit 231 advances the processing to the reset determination step S528.

  In this way, the cost of the flashing device 101 can be reduced by omitting the function of evacuation guidance using a guide sound. Thereby, since more flashing devices 101 can be installed, the area of the floor surface that can be irradiated in the event of an earthquake is further expanded, and safe evacuation can be achieved.

  The evacuation guidance system 800 may have a configuration in which the blinking device 101 described in at least one of the fourth and fifth embodiments and the blinking device 101 described in this embodiment are mixed.

Embodiment 7 FIG.
The seventh embodiment will be described with reference to FIG.
In addition, about the part which is common in Embodiment 6, the same code | symbol is attached | subjected and description is abbreviate | omitted.

FIG. 20 is a perspective view showing the appearance of the flashing device 101 in this embodiment.
The flashing device 101 is installed, for example, embedded in the ceiling surface, similarly to the flashing device 101 described in the fifth embodiment.

  Even if the blinking device 101 has such a configuration, the same effects as those of the sixth embodiment can be obtained.

  The evacuation guidance system 800 may have a configuration in which the blinking device 101 described in at least one of Embodiments 4 to 6 and the blinking device 101 described in this embodiment are mixed.

Embodiment 8 FIG.
An eighth embodiment will be described with reference to FIGS.
In addition, about the part which is common in Embodiment 3, the same code | symbol is attached | subjected and description is abbreviate | omitted.

FIG. 21 is a normal partial cross-sectional view showing the structure of the flashing unit 130 in this embodiment.
The flashing unit 130 further includes a rotating unit 136 and a reflecting unit 137 in addition to the configuration described in the third embodiment.
The rotating unit 136 includes, for example, a motor and a rotating shaft. The rotating unit 136 rotates around an axis in a direction that is substantially vertical when the guide lamp device 100 is installed.
The reflecting portion 137 is fixed to the tip of the rotating portion 136 so as to be rotatable about a direction that is substantially horizontal when the guide lamp device 100 is installed. The surface of the reflection part 137 reflects light.
The cover 135 has a substantially cylindrical shape and covers the LED 133 and the reflecting portion 137.

FIG. 22 is a block diagram showing the configuration of the blinking circuit 231 in this embodiment.
The blinking control circuit 265 generates a signal for controlling the operation of the rotating unit 136. The blinking control circuit 265 controls the rotating unit 136 according to the blinking control signal input from the control input terminal 234. When the blinking control signal instructs blinking, the blinking control circuit 265 rotates the rotating unit 136. The rotating unit 136 rotates at a rate of about twice per second according to the signal from the blinking control circuit 265. In other cases, the blinking control circuit 265 stops the rotating unit 136.
The blinking control circuit 265 controls the lighting circuit 267 according to the blinking control signal input from the control input terminal 234. When the lighting control signal instructs to turn off, the blinking control circuit 265 stops the operation of the lighting circuit 267 and turns off the LED 133. When the lighting control signal instructs blinking lighting or continuous lighting, the blinking control circuit 265 operates the lighting circuit 267 to continuously light the LED 133.

FIG. 23 is a schematic diagram showing the movement of the blinking unit 130 in this embodiment.
When the rotating unit 136 is not rotating, the reflecting unit 137 is in a position depending on the action of gravity or the like. For this reason, the light emitted from the LED 133 is not reflected by the reflecting portion 137 but reaches the floor as it is.
When the rotating unit 136 is rotating, the reflecting unit 137 rotates around the rotation axis while crossing the front of the LED 133 by the action of centrifugal force or the like. The light emitted by the LED 133 is reflected by the reflecting portion 137 and is emitted in a substantially horizontal direction.

When the blinking control signal input from the control input terminal 234 instructs to turn off or continuously light, the blinking control circuit 265 stops the rotation of the rotating unit 136. When the blinking control signal instructs continuous lighting, the light emitted by the LED 133 is emitted to the substantially vertical downward direction without being reflected by the reflecting portion 137, and irradiates the floor surface.
When the blinking control signal input from the control input terminal 234 instructs blinking lighting, the blinking control circuit 265 rotates the rotating unit 136. The light emitted from the LED 133 is reflected by the reflecting portion 137 at a rate of about twice per second and is emitted in a substantially horizontal direction. Thereby, when the guide light device 100 is viewed from a substantially horizontal direction, the light reflected by the reflecting portion 137 seems to blink at a rate of about twice per second.

  Thereby, the light which LED133 radiated | emitted can be shared by the floor surface irradiation at the time of the earthquake occurrence, and the blinking at the time of the fire outbreak.

Embodiment 9 FIG.
Embodiment 9 will be described with reference to FIG.
In addition, about the part which is common in Embodiment 4, the same code | symbol is attached | subjected and description is abbreviate | omitted.

FIG. 24 is a normal partial cross-sectional view showing the structure of the flashing unit 130 in this embodiment.
The blinking device 101 is a wall surface embedded type, and the blinking unit 130 is provided on the side surface of the instrument main body 110.
The blinking unit 130 includes an LED 133, a cover 135, and a reflecting unit 137.
The surface of the reflection part 137 reflects light. The reflecting portion 137 is positioned substantially in front of each LED 133 and rotates about the substantially horizontal direction. The blinking control circuit 265 controls the angle of the reflection unit 137.

When the blinking control signal input from the control input terminal 234 instructs blinking lighting, the blinking control circuit 265 sets the angle of the reflecting portion 137 to about 45 degrees and causes the LED 133 to blink. The light emitted by the LED 133 is reflected by the reflecting portion 137, reflected by the back side of the reflecting portion 137 located below the reflecting portion 137, and emitted in a substantially horizontal direction.
When the blinking control signal input from the control input terminal 234 instructs continuous lighting, the blinking control circuit 265 sets the angle of the reflecting portion 137 to a shallower angle (for example, 30 degrees) than that during blinking lighting, and continuously turns on the LED 133. The light emitted from the LED 133 is reflected by the reflecting portion 137 and irradiates the floor surface.

  Thereby, the light which LED133 radiated | emitted can be shared by the floor surface irradiation at the time of the earthquake occurrence, and the blinking at the time of the fire outbreak.

  DESCRIPTION OF SYMBOLS 100 Guide light apparatus, 101 Flashing apparatus, 110 Apparatus main body, 111 Opening hole, 120 Display part, 121 Display main body, 122 Symbol surface, 123 Display panel, 124 Light guide plate, 125 Display light source part, 126, 133 LED, 127, 134 Printed wiring board, 128 lamp holder, 130 flashing part, 131 xenon lamp, 132 xenon lamp socket, 135 cover, 136 rotating part, 137 reflecting part, 140 control circuit, 144 fire judgment part, 145 earthquake judgment part, 146 control signal generation , 151 speaker, 160 power terminal block, 161-164, 171, 172, 181, 182 electric wire insertion hole, 170 fire signal terminal block, 180 earthquake signal terminal block, 191-197 electric wire, 220 guide light unit, 221 guide light Circuit, 222, 2 2 Battery, 223, 233, 243 Power supply terminal, 224, 234 Control input terminal, 230 Flashing unit, 231 Flashing circuit, 235 Guided sound output unit, 240 Control unit, 246, 247 Control output terminal, 244 Fire input terminal, 245 Earthquake Input terminal, 251 261 power supply circuit, 252 262 power failure judgment unit, 253, 263 power switching circuit, 254, 264 charge / discharge circuit, 255 illuminance setting circuit, 256, 266, 267 lighting circuit, 265 blinking control circuit, 800 evacuation Guidance system, 810 Power distribution equipment, 820 Fire alarm equipment, 830 Emergency broadcast equipment, 891 Power line, 892 Fire signal line, 893 Earthquake signal line.

Claims (3)

An earthquake determination unit for determining the occurrence of an earthquake;
A fire judgment unit for judging the occurrence of a fire;
When the fire determination unit determines that a fire has occurred, it blinks and lights, and when the fire determination unit does not determine that a fire has occurred and the earthquake determination unit determines that an earthquake has occurred, I have a,
The light source unit includes a first light source unit that emits light in a direction that is substantially horizontal during installation, and a second light source unit that emits light in a direction that is substantially vertical downward during installation. ,
The first light source unit blinks when the fire determination unit determines that a fire has occurred,
The second light source unit blinks when the fire determining unit determines that a fire has occurred, the fire determining unit does not determine that a fire has occurred, and the earthquake determining unit determines that an earthquake has occurred. A flashing device characterized by continuous lighting . A blinking device according to claim 1 ;
A power failure judgment unit for judging a power failure;
A display unit for displaying an evacuation guidance pattern;
A display light source unit that emits light that illuminates the display unit,
The display light source unit emits light having a first illuminance when the power failure determination unit does not determine a power failure, the power failure determination unit determines a power failure, and the fire determination unit determines that a fire has occurred. A second illuminance light that is darker than the first illuminance, the power failure determination unit determines a power failure, the fire determination unit does not determine that a fire has occurred, and the earthquake determination unit Emits light having a third illuminance that is darker than the second illuminance when it is determined that an earthquake has occurred. And guide light device according to flashers or claim 2 according to claim 1,
An earthquake early warning receiving device for receiving the earthquake early warning,
An evacuation guidance system, wherein the earthquake determination unit determines that an earthquake has occurred when the emergency earthquake warning reception device receives an emergency earthquake warning.

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