KR100876649B1 - Lamp for guiding escape direction when disaster happens - Google Patents

Abstract

It is an object of the present invention to provide an evacuation induction lamp for guiding a way to a safe emergency exit among emergency exits installed in the facility when a disaster occurs in the facility. In order to achieve the above object, the present invention is installed in a facility, in the evacuation induction lamp connected to the first power line and the second power line, a disaster detection unit for detecting a disaster occurring in the facility; A direction indicator indicating a direction to an emergency exit installed in the facility; A power line communication unit configured to perform power line communication with external devices through the first and second power lines; A control unit which receives the output signal of the disaster detection unit and the output signal of the power line communication unit and controls the direction display of the direction display unit; And a control unit, a power line communication unit, a first power line, and a second power line, and connect or disconnect the first power line and the second power line in response to an output signal of the control unit, and the power of the first and second power lines. An evacuation induction lamp having a line switching unit for connecting the supplied power line to the power line communication unit is provided.

Description

Lamp for guiding escape direction when disaster happens}

1 is a view illustrating a state in which an evacuation induction lamp is connected to a first power line and a second power line according to a preferred embodiment of the present invention.

FIG. 2 shows a state in which the evacuation induction lamp of FIG. 1 is connected to external devices.

3 illustrates an example of the direction display unit of FIG. 1.

4 shows a state where a plurality of evacuation induction lamps are installed in the facility.

5 is a flowchart illustrating a method of determining a disaster by the controller of FIG. 1.

6 is a flowchart illustrating in detail the second and third steps of FIG. 5.

FIG. 7 is a flowchart illustrating an operation of another evacuation induction lamp that is notified by the power line communication unit that the section in which the disaster detection unit is installed is determined to be a dangerous area in the fourth step of FIG. 5.

The present invention relates to an evacuation induction lamp, and more particularly, to an evacuation induction lamp that informs the evacuation direction when a disaster occurs in a facility.

In the buildings where many people live, there are guide lights to guide emergency exits in case of disasters. The induction lamp is turned on by a commercial AC power source, and has a separate rechargeable battery in case of power failure or fire. The rechargeable battery is charged by commercial AC power when the induction lamp is not lit. Therefore, when a disaster such as a power failure or a fire occurs and the commercial AC power is not supplied to the induction lamp, the rechargeable battery operates to turn on the induction lamp.

By the way, such a conventional induction lamp displays only one direction. That is, even if a disaster occurs, the induction lamp performs only a function of inducing in a predetermined direction regardless of the location of the disaster. If a disaster occurs in the direction indicated by the induction light, the induction light does not lead people to a safe place, but rather leads to a dangerous area. As a result, the chance of early evacuation is lost, resulting in many lives.

It is an object of the present invention to provide an evacuation induction lamp for guiding a person to change and guide a safe route to emergency exits installed in the facility in the event of a disaster in the facility.

The present invention to achieve the above object,

Installed in the facility, the evacuation induction lamp connected to the first power line and the second power line, the disaster detection unit for detecting a disaster occurring in the facility; A direction indicator indicating a direction to an emergency exit installed in the facility; A power line communication unit configured to perform power line communication with external devices through the first and second power lines; A control unit which receives the output signal of the disaster detection unit and the output signal of the power line communication unit and controls the direction display of the direction display unit; And a control unit, a power line communication unit, a first power line, and a second power line, and connect or disconnect the first power line and the second power line in response to an output signal of the control unit, and the power of the first and second power lines. An evacuation induction lamp having a line switching unit for connecting the supplied power line to the power line communication unit is provided.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. Like reference numerals in the drawings denote like elements.

Figure 1 shows a state in which the evacuation induction lamp is connected to the first and second power lines in accordance with a preferred embodiment of the present invention. Referring to FIG. 1, the evacuation induction lamp 101 includes a disaster detection unit 111, a direction display unit 121, a power line communication unit 131, a memory 141, a power supply unit 151, a battery 161, and a control unit. 171 and a line switching section 181 are provided. The evacuation induction lamp 101 is installed in the facility and is connected to the first power line 191 and the second power line 192. Preferably, a plurality of first power lines 191 and second power lines 192 are provided.

The first and second power lines 191 and 192 transmit power. The power transmitted through the first and second power lines 191 and 192 generally has a commercial voltage between 100 volts and 240 volts. The first power line 191 and the second power line 192 are normally connected to each other, and when an abnormality occurs in any one of the first power line 191 or the second power line 192, the line switching unit ( 181).

The disaster detection unit 111 is installed in a facility and detects a disaster occurring in the surroundings. The disaster detection unit 111 includes a wind direction, a wind speed sensor, a flame sensor, a temperature sensor, a smoke sensor, and the like to detect a disaster such as a fire, and transmit the result to the controller 171.

The direction indicator 121 is installed near the passages leading to the emergency exits installed in the facility. The direction display unit 121 indicates a direction toward safe emergency exits which are not affected by the disaster among the emergency exits when a disaster occurs. The direction display unit 121 may display only one direction but may also display a plurality of directions.

The power line communication unit 131 is connected to the first power line 191 and the second power line 192 through a communication line switching unit. The power line communication unit 131 performs power line communication with external devices through the first power line 191 and the second power line 192. That is, when a disaster occurs, the controller 171 receives an instruction from the controller 171 to inform external devices 211 and 221 of FIG. 2 through the power line communication.

The memory 141 is connected to the controller 171 and stores data transmitted from the controller 171. In the memory 141, an algorithm for determining a safe path to emergency exits installed in the facility by analyzing disaster-related data detected by the disaster detection unit 111 and state information of external devices 211 and 221 of FIG. Stored. The memory 141 may include random access memory (RAM) or flash memory.

The power supply unit 151 is connected to the power line switching unit 185 and the power switching unit 186. The power supply unit 151 receives power from the first power line 191 or the second power line 192 through the power line switching unit 185, and the control unit 171 and the power line communication unit 131 through the power switching unit 186. ) And the direction display unit 121 to supply power. The power supply unit 151 decompresses and rectifies the power supplied from the first power line 191 or the second power line 192 with the power required for the operation of the evacuation induction lamp 101 to control the controller 171, the power line communication unit 131, and the direction. The display unit 121 is supplied to charge the storage battery 161.

The storage battery 161 is connected to the power supply unit 151 and the power switching unit 186, and normally receives power from the power supply unit 151 and is kept in a charged state, and the power supply unit 151 when the power supply of the power supply unit 151 is disconnected. Instead, the power supply unit 186 supplies power to the control unit 171, the power line communication unit 131, and the direction display unit 121.

The controller 171 is connected to the disaster detection unit 111, the memory 141, the direction display unit 121, the power line communication unit 131, and the line switching unit 181. The control unit 171 receives the output signal of the disaster detection unit 111 and determines whether a disaster has occurred around the disaster detection unit 111. When the controller 171 determines that a disaster has occurred, the controller 171 informs the external devices (211 and 221 of FIG. 2) connected to the first power line 191 and the second power line 192 through the power line communication unit 131, In addition, it receives whether a disaster occurs from the external devices (211, 221 of Figure 2). The controller 171 also searches for a safe route to emergency exits in the event of a disaster, and controls the direction indicator 121 to indicate a safe route where the disaster has not occurred.

The line switching unit 181 is connected to the controller 171, the power line communication unit 131, the direction display unit 121, the power supply unit 151, the storage battery 161, the first power line 191, and the second power line 192. . The line switching unit 181 interconnects or disconnects the first power line 191 and the second power line 192 in response to the output signal of the controller 171, and the first power line 191 and the second power line 192. ) Connects a power line to which power is supplied to the controller 171, the power line communication unit 131, and the direction display unit 121.

The line switching unit 181 includes a communication line switching unit 183, a line power blocking unit 184, a power line switching unit 185, and a power switching unit 186.

The communication line switching unit 183 is connected to the controller 171, the power line communication unit 131, the first power line 191, and the second power line 192. The communication line switching unit 183 connects one of the first power line 191 and the second power line 192 to the power line communication unit 131 under the instruction of the control unit 171. The communication line switching unit 183 normally connects the first power line 191 to the power line communication unit 131. Since power is initially transmitted through the first power line 191, normally and initially, the communication line switching unit 183 connects the first power line 191 to the power line communication unit 131. Accordingly, the power line communication unit performs power line communication with the external device through the first power line. Then, when the power line communication through the first power line 191 is blocked, it is confirmed that the power line communication is blocked by the power line communication unit, and the controller 171 causes the communication line switching unit 183 to connect the second power line 192 to the power line communication unit. (131).

The line power interrupter 184 is installed between the first power line 191 and the second power line 192. The line power cutoff unit 184 is normally maintained in an off state, whereby the first power line 191 and the second power line 192 are disconnected from each other. The line power cutoff unit 184 receives an output signal of the control unit 171, thereby turning on the first power line 191 and the second power line 192.

The power line switching unit 185 is connected to the power switching unit 186, the power supply unit 151, the first power line 191, and the second power line 192. The power line switching unit 185 normally connects the second power line 192 to the power switching unit 186 and the power supply unit 151. Initially, power is transmitted through the first power line 191. Accordingly, the power line switching unit 185 connects the first power line 191 to the power switching unit 186 and the power supply unit 151. Therefore, the power supply unit 151 initially receives power from the first power line 191. This state continues unless an abnormality occurs in the first power line 191 and the second power line 192. If an abnormality occurs in the first power line 191, the line power cutoff unit 184 is cut off by the controller 171. Then, the power line switching unit 185 connects the second power line 192 to the power supply unit 151 and the power switching unit 186 as usual. In this case, the power supply unit 151 receives power from the second power line 192. If an abnormality occurs in the second power line 192 and the power is cut off, the evacuation induction lamp 101 is no longer supplied with power from the first power line 191 and the second power line 192, and is switched to the communication line. 183, the line power interrupter 184, the power line switch 185, and the power switch 186 all return to their usual states. When the power switching unit 186 is in the usual state, each part requiring power such as the direction display unit 121, the power line communication unit 131, and the control unit 171 is connected to the storage battery 161, and the storage battery 161 is connected to the storage battery 161. Let the power supply.

As such, the power line switching unit 185 detects the power of the first power line 191 and the second power line 192 without performing the control of an external device and performs a switching operation by itself. That is, the power line switching unit 185 normally connects the second power line 192 to the power switching unit 186 and the power supply unit 151, and detects the power as soon as power is transmitted through the first power line 191. By connecting the first power line 191 to the power switch 186 and the power supply unit 151.

The power switching unit 186 is connected to the control unit 171, the power line communication unit 131, the direction display unit 121, the power line switching unit 185, the power supply unit 151, and the storage battery 161. The power switch 186 connects the power supply unit 151 to the control unit 171, the power line communication unit 131, and the direction display unit 121 while power is supplied from the first power line 191 or the second power line 192. . Then, as soon as the power supply is disconnected from the first power line 191 or the second power line 192, the storage battery 161 is connected to the control unit 171, the power line communication unit 131, and the direction display unit 121. The power switching unit 186 normally connects the storage battery 161 to the control unit 171, the power line communication unit 131, and the direction display unit 121. When power is transmitted through the first power line 191 or the second power line 192, the power switching unit 186 supplies the power supply unit 151 to the control unit 171, the power line communication unit 131, and the direction display unit 121. Connect it.

As such, the power switching unit 186 detects the power output from the power line switching unit 185 without performing control of another device and performs a switching operation by itself. That is, the power switching unit 186 is the control unit 171, the power line communication unit 131 and the power supply unit 151 while the power is supplied to the power supply unit 151 through the first power line 191 or the second power line 192. The power is supplied to the direction display unit 121, and when the power supply is disconnected to the power supply unit 151 through the first power line 191 or the second power line 192, the controller 171 detects the power supply from the battery 161. The power is supplied to the power line communication unit 131 and the direction display unit 121.

FIG. 2 shows a state where the evacuation induction lamp 101 of FIG. 1 is connected to external devices 211 and 221, such as other induction evacuation lights and / or a higher level control device. As shown in FIG. 2, the evacuation induction lamp 101 may perform power line communication with the external devices 211 and 221 through the first power line 191 and the second power line 192. Therefore, when the evacuation induction lamp 101 detects a disaster such as a fire, the emergency devices are immediately notified to the external devices 211 and 221 so that the external devices 211 and 221 prevent damage caused by the disaster.

3 illustrates an example of the direction display unit 121 of FIG. 1. Referring to FIG. 3, the direction display unit 121 has a plurality of direction indications 311 and 321. The plurality of direction marks 311 and 321 indicate a direction to a plurality of emergency exits installed in the facility. The plurality of direction indications 311 and 321 are turned on or off. That is, the lit direction indicator indicates the direction to the safe emergency exit, and the unlit direction indicator indicates the direction to the emergency exit where a disaster has occurred. The plurality of direction indications 311 and 321 may all be turned on, all may be turned off, or only some of them may be turned on. If the plurality of direction indicators 311 and 321 are all lit, the emergency exits in the direction indicated by the plurality of direction indicators 311 and 321 are all safe. If the plurality of direction indicators 311 and 321 are all off, the plurality of direction indicators are turned off. Emergency exits in the direction indicated by fields 311 and 321 indicate that there is a risk of disaster.

Unlike FIG. 3, the direction display unit 121 may have only one direction display. In this case, only two operations in which the one direction indicator is turned on or off are performed. If the one direction indicator is lit, the one direction indicator indicates the direction to a safe emergency exit, and if the one direction indicator is off, the direction indicated by the one direction indicator indicates that the emergency exit has a risk of disaster. Indicates.

4 shows a state where a plurality of evacuation induction lamps A1 to D1 are installed in the facility. Referring to FIG. 4, a plurality of evacuation induction lamps A1 to D1 are provided for passages leading to the emergency exits A to D. The plurality of evacuation induction lamps A1 to D1 are interconnected by power lines 191 and 192 of FIG. 1.

Explain the case of a fire in the area where the evacuation induction lamp (A2) is installed. Evacuation induction lights (A1, A2, A3) are A emergency exit, evacuation induction lights (B1, B2) are emergency exit B, evacuation induction lights (C1, C2, C3) are emergency exit C, evacuation induction light (D1) is D It is initially set to point to an emergency exit, and this setting takes precedence as the default.

Assume that a fire occurred near the evacuation guidance light (A2). Evacuation induction lamp (A2) calculates the fire hazard coefficients at regular intervals, and when it is determined that the fire condition has reached the dangerous level, it informs the other evacuation induction lamps (A1, A3 to D1) of the power line communication. At this time, evacuation induction light (A1) is determined as the risk of its own risk is not yet a big emergency exit direction indicator selected as the default direction, evacuation induction light (A3) is the highest priority evacuation induction light in the direction of A exit. In (A2), a signal indicating that the danger area is received through power line communication is changed, and the direction is indicated by the second priority D emergency exit. Evacuation guidance lamps D1, B1, B2, C1, C2, C3 installed near the emergency exits B, C have a low fire hazard coefficient and do not need to change the initial direction indication. . If, over time, the fire spreads to the D emergency exit area, the evacuation guidance light (A3) changes direction indication to the B emergency exit by the fire hazard signal of the evacuation guidance lights (A3, D1). At this time, since there is a time difference between the fire risk detection of the evacuation induction lamp (A3) and the fire risk detection of the evacuation induction lamp (D1), it is possible to know the direction in which the fire is moved by analyzing this in the upper control device. Therefore, by using the data analyzed by the higher-level control device, it is possible to easily perform the fire suppression and rescue. In addition, when the power lines 191 and 192 of FIG. 1 are damaged due to fire over time, a safety circuit breaker (not shown) connected to the power lines 191 and 192 of FIG. 1 operates to stop the power supply to the entire power lines 191 and 192. Then, power line communication is also interrupted in sections following the A & D emergency exits, so that the evacuation induction lamps A1, A3 to D1 are switched to the storage mode of the battery (161 in FIG. 1) to the A & D emergency exits. Power line communication in sections other than the subsequent sections is maintained and information is continuously shared. In addition, since the last information is recorded in the memory of the evacuation guidance lamps of other sections before the communication interruption, the fire information generated in the emergency exits of the A & D emergency exits is used. You can decide. In addition, evacuation induction lamps A1, A2, A3, and D1 installed in A & D emergency exits that have lost communication maintain the direction indication determined by the last information until they are damaged by fire.

5 is a flowchart illustrating a method of determining a disaster by the controller 171 of FIG. 1. The disaster determination method illustrated in FIG. 5 will be described with reference to FIG. 1. Referring to FIG. 5, the disaster determination method includes first to sixth steps 511 to 561.

In a first step 511, the control unit 171 receives an output signal of the disaster detection unit 111 and calculates a disaster risk coefficient. The output signal of the disaster detection unit 111 includes a temperature coefficient and a smoke concentration coefficient.

In a second step 521, the controller 171 compares the calculated value of the disaster risk coefficient with a preset reference value k.

In a third step 531, when the disaster risk factor is greater than the reference value k, the controller 171 determines the area where the disaster detection unit 111 is installed as a disaster danger area.

In a fourth step 541, when the area where the disaster detection unit 111 is installed is determined as a disaster risk area, the power line communication unit 131 notifies the facts to the external devices 211 and 221 of FIG. 2.

In a fifth step 551, when the direction display unit 121 instructs the direction to the emergency exit located in the disaster danger zone, the control unit 171 switches the direction to another safe emergency exit, and the direction display unit 121 If you are in the direction of the other safe exit, keep it.

As the sixth step 561, unless the emergency induction lamp 101 has an abnormality such as breakage, the first to fifth steps 511 to 551 are repeated, and an abnormality occurs in the evacuation induction lamp 101. Otherwise, when the power supply to the power lines 191 and 192 is cut off and power is supplied from the storage battery 161, the power of the storage battery 161 is discharged.

6 is a flowchart illustrating in detail the second step 521 and the third step 531 of FIG. The method illustrated in FIG. 6 will be described with reference to FIG. 1.

As a first step 611, the controller 171 compares the temperature coefficient with the temperature reference value k1.

In a second step 621, the control unit 171 compares the smoke concentration coefficient with the smoke concentration reference value k2.

As a third step, if the temperature coefficient is greater than the temperature reference value k1 and the smoke concentration coefficient is greater than the smoke concentration reference value k2, the controller 171 may be a section in which the disaster detection unit 111 is installed. Is determined to be a fire and asphyxiation zone (631).

If the temperature coefficient is greater than the temperature reference value k1 and the smoke concentration coefficient is not greater than the smoke concentration reference value k2, the controller 171 controls the section in which the disaster detection unit 111 is installed in a flame hazard zone. In operation 632.

If the temperature coefficient is not greater than the temperature reference value k1 and the smoke concentration coefficient is larger than the smoke concentration reference value k2, the controller 171 may be configured to pass the section where the disaster detection unit 111 is installed in the asphyxiated danger zone. (633).

If the temperature coefficient is not greater than the temperature reference value k1 and the smoke concentration coefficient is not greater than the smoke concentration reference value k2, the controller 171 controls the section in which the disaster detection unit 111 is installed in a safe area. It is determined as (634).

 FIG. 7 is a flowchart illustrating an operation of another evacuation induction lamp that is notified by the power line communication unit 131 that the section in which the disaster detection unit 111 is installed is determined to be a dangerous area in FIG. 5. The method illustrated in FIG. 7 will be described with reference to FIG. 2.

As a first step 711, the other evacuation guide lights 211, 221 confirm that the disaster hazard zone is located in the direction indicated by the direction indicators.

As a second step 721, if the danger zone is located in the direction indicated by the direction indicators of the other evacuation guidance lights 211,221, the other evacuation guidance lights 211,221 display the direction indication of the direction indication parts in another safe manner. Switch to the exits.

If the danger zone is not located in the direction indicated by the direction indicators of the other evacuation guide lights 211 and 221, the other evacuation guide lights 211 and 221 are routed to the emergency exits in the direction indicated by the direction indicators. Check if it is safe, keep the direction signs if safe, and switch the direction signs to another safe route except the dangerous area if not safe.

As a third step 731, repeat steps 711, 721, 722 as long as the other evacuation guidance lights 211, 221 are not broken, and if other evacuation guidance lights 211, 221 do not occur or power line When the power supply to the fields 191 and 192 is cut off and power is supplied from the storage battery 161 of FIG. 1, when the power of the storage battery 161 of FIG. 1 is discharged, all the above processes are completed.

8 is a block diagram of an evacuation induction lamp according to another embodiment of the present invention. Referring to FIG. 8, the evacuation induction lamp 801 includes a disaster detection unit 111, a direction display unit 121, a wireless communication unit 831, a memory 141, a power supply unit 151, a storage battery 161, and a control unit 871. And a line switching unit 881. The evacuation induction lamp 801 is installed in the facility and is connected to the first power line 191 and the second power line 192.

The evacuation induction lamp of FIG. 8 is similar in configuration to the evacuation induction light of FIG. 1. However, the evacuation induction lamp 801 of FIG. 8 includes a wireless communication unit 831 instead of the power line communication unit 131 of FIG. 1, and the line switching unit 831 of FIG. 8 includes the communication line switching unit 183 of FIG. 1. I never do that. Therefore, only portions that differ from FIG. 1 will be described in order to avoid redundant description.

The wireless communication unit 831 wirelessly communicates with external devices, for example, other evacuation induction lamps 211 and 221 of FIG. 2. That is, when a disaster occurs, the wireless communication unit 831 wirelessly notifies the external devices (211 and 221 of FIG. 2) of the occurrence of the disaster by receiving an instruction of the controller 831.

When a disaster occurs, the controller 871 notifies the external devices (211 and 221 of FIG. 2) that the disaster has occurred through the wireless communication unit 831, and searches for a safe path without a disaster among the paths to the emergency exits. The direction indicator 121 directs the safe path.

As such, the evacuation induction lamp 801 informs people of a safe route to emergency exits installed in the facility when a disaster occurs in the facility, and also informs the external devices (211, 221 of FIG. 2) of the disaster by wireless communication. By reducing the risk of life. In addition, since the evacuation induction lamp 801 communicates wirelessly with the external devices 211 and 221 of FIG. 2, there is no need to install a wire. Therefore, the installation of the evacuation induction lamp 801 is easy.

As described above, the evacuation induction lamp (101,801) according to the present invention tells people a safe route to emergency exits installed in the facility in the event of a disaster in the facility.

Therefore, even if a disaster occurs, people in the facility do not suffer from the disaster if they go in the direction indicated by the evacuation induction lamp 101.

Although the present invention has been described with reference to the embodiments shown in the drawings, this is merely exemplary, and it will be understood by those skilled in the art that various modifications and equivalent other embodiments are possible. Therefore, the true technical protection scope of the present invention will be defined by the technical spirit of the appended claims.

Claims (11)

In the evacuation induction lamp installed in the facility, connected to the first power line and the second power line, A disaster detection unit for detecting a disaster occurring in the facility; A direction indicator indicating a direction to an emergency exit installed in the facility; A power line communication unit configured to perform power line communication with external devices through the first and second power lines; A control unit which receives the output signal of the disaster detection unit and the output signal of the power line communication unit and controls the direction display of the direction display unit; And The first power line and the second power line are connected or disconnected in response to an output signal of the control unit, and power is disconnected from the first power line and the second power line. Evacuation guidance lamp characterized in that it comprises a line switching unit for connecting the power line supplied to the power line communication unit. The method of claim 1, wherein the evacuation induction lamp A power supply unit supplying power to the control unit, the power line communication unit, and the direction display unit; And And a storage battery connected to the power supply unit and maintained in a charged state, and further configured to supply power to the control unit, the power line communication unit, and the direction display unit instead of the power supply unit when the power supply unit is disconnected. According to claim 2, wherein the line switching unit A power line switching unit connected to the power supply unit, a first power line, and a second power line, and connecting a power line to which power is being transmitted among the first and second power lines; And Evacuated between the first power line and the second power line, it is connected to the control unit, evacuation characterized in that it comprises a line power cut-off unit for connecting or disconnecting the first and second power lines in response to the output signal of the control unit; Induction light. According to claim 1, wherein the line switching unit And a communication line switching unit connected to the power line communication unit, the first power line, and the second power line and connecting a power line capable of power line communication among the first and second power lines to the power line communication unit. According to claim 2, wherein the line switching unit The power supply unit is connected to the control unit, the direction display unit, the power line communication unit, the power supply unit, the battery, the first power line and the second power line, and when power is input from the power supply unit from the first power line or the second power line. And a power switch connected to the communication unit and connecting the storage battery to the control unit, the direction display unit, and the power line communication unit when power is not input to the power supply unit from the first power line or the second power line. According to claim 1, It is connected to the control unit, receives the disaster-related data detected by the disaster detection unit and the status information of the other evacuation induction light connected to the evacuation induction light and analyze them to find a safe path to the emergency exits installed in the facility Evacuation induction lamp, characterized in that further comprising a stored memory to determine the algorithm. In the evacuation induction lamp installed in the facility, connected to the first power line and the second power line, A disaster detection unit for detecting a disaster occurring in the facility; A direction indicator indicating a direction to an emergency exit installed in the facility; Wireless communication with external devices connected to the evacuation induction lamp is provided through the first and second power lines. Performing a wireless communication unit; A control unit which receives the output signal of the disaster detection unit and the output signal of the wireless communication unit and controls the direction display of the direction display unit; A memory for storing data transmitted from the control unit; and A first power line and a second power line connected to or disconnected from the wireless communication unit, the control unit, the first power line, and the second power line; Evacuation guidance lamp comprising a line switching unit for connecting the supplied power line to the wireless communication unit. The method of claim 7, wherein the evacuation induction lamp A power supply unit supplying power to the control unit, the wireless communication unit, and the direction display unit; And And a storage battery connected to the power supply unit and maintained in a charged state, wherein the storage unit further supplies power to the control unit, the wireless communication unit, and the direction display unit when the power supply unit is disconnected. The method of claim 8, wherein the line switching unit A power line switching unit connected to the power supply unit, a first power line, and a second power line, and connecting a power line to which power is being transmitted among the first and second power lines; And Evacuated between the first power line and the second power line, it is connected to the control unit, evacuation characterized in that it comprises a line power cut-off unit for connecting or disconnecting the first and second power lines in response to the output signal of the control unit; Induction light. The method of claim 8, wherein the line switching unit The power supply unit is connected to the control unit, the direction display unit, the wireless communication unit, the power supply unit, the battery, the first power line and the second power line, and when power is input from the power supply unit from the first power line or the second power line. And a power switching unit connected to the communication unit and connecting the storage battery to the control unit, the direction display unit, and the wireless communication unit when power is not input to the power supply unit from the first power line or the second power line. According to claim 7, The algorithm stored in the memory receives the disaster-related data detected by the disaster detection unit and the status information of the other evacuation guidance light connected to the evacuation guidance light and analyze them to determine the safety route to the emergency exits installed in the facility Evacuation induction lamp, characterized in that judging.

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