KR100876648B1 - Escape leading system for guiding safe course when disaster happens - Google Patents

Abstract

An escape guiding system is provided to minimize damage of human life by moving people to a safe course by approach light when disaster occurs. A plurality of power lines(122) transmits a power. A plurality of fire sensors(151a-151m) is connected to the power line in order to sense a fire. A plurality of approach lights(141a-141n) guides an exit installed at a building. A plurality of power line communications parts(131a-131n) includes sub switching devices(133a-133n), an induction controller, and a power supply unit, and controls the approach lights according to a fire signal outputted from the fire sensor. The approach light indicates a safe course without influence of the fire. A power line sensor(111) is connected to both ends of a plurality of power lines.

Description

Escape leading system for guiding safe course when disaster happens}

1 is a block diagram of the evacuation guidance system of the present invention connected to a control center.

FIG. 2 shows one of the induction lamps shown in FIG. 1.

3 shows a state in which the induction lamp shown in FIG. 2 is installed in a facility.

4 is a detailed block diagram of one of the powerline communication units of FIG. 1 connected to powerlines.

The present invention relates to an evacuation guidance system, and more particularly to an evacuation guidance system that leads people in a building to a safe path when a disaster such as a fire occurs in the building.

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 commercial power supply is not supplied to the induction lamp due to a disaster such as a power failure or a fire, 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 guidance system that leads people in a facility to a safe emergency exit in the event of a disaster in the facility.

The present invention to achieve the above object,

An evacuation guidance system installed in a facility, comprising: a plurality of power lines for transmitting power; A plurality of fire detectors connected to the power lines for detecting a fire; A plurality of induction lights installed in the facility to guide the way to one or more emergency exits installed in the facility; The induction lamps are connected to the plurality of power lines and the plurality of induction lamps and receive a fire signal output from a fire detector that detects a fire among the plurality of fire detectors. A plurality of power line communication units controlling to instruct; And a power line monitoring unit connected to both ends of the plurality of power lines, wherein the plurality of power lines are divided into a plurality of sections, and the power line monitoring unit monitors whether there is an abnormality of the power lines, and when the abnormality is detected, the plurality of power lines. Detecting a section in which an abnormality occurs while supplying power sequentially to each section, and detecting a section in which an abnormality occurs while supplying power in the reverse order to the plurality of sections, cutting off power in the section in which the abnormality occurs, and generating the abnormality. Power on all sections that are not.

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.

1 is a block diagram of the present invention connected to a control center. Referring to FIG. 1, the evacuation guidance system 101 includes a plurality of power lines 122, a plurality of fire detectors 151a through 151m, a plurality of induction lamps 141a through 141n, and a plurality of power line communication units 131a through. 131n) and a power line monitoring unit 111. The evacuation guidance system 101 is installed in the building, and when a fire occurs, the contents are transmitted to the control center 181, which is a kind of a host apparatus, through a wireless, wired or power lines 221.

The plurality of power lines 122 transmits power. Power transmitted over power lines 122 typically has a commercial voltage between 100 volts and 240 volts. The power lines 122 are divided into a plurality of sections L1 to Ln + 1. For example, a first section L1 is formed between the power line detector 111 and the first power line communication unit 131a, and a second section L2 is disposed between the first power line communication unit 131a and the second power line communication unit 131b. Are distinguished.

The plurality of fire detectors 151a to 151m are connected to the power lines 122 to detect a fire. That is, the plurality of fire detectors 151a to 151m operate by receiving power supplied from the power lines 122, and detect a fire by including a heat sensor, a temperature sensor, a replay sensor, a wind direction sensor, and an atmospheric pressure sensor. do. Each of the plurality of fire detectors 151a to 151m includes a power line communication device (not shown), and when a fire occurs, a short circuit is output and transmitted to the plurality of power line communication units 131a to 131n to indicate that a fire has occurred. Inform. The plurality of fire detectors 151a to 151m are installed where a fire in the facility may occur.

A plurality of induction lamps 141a to 141n are installed in the passage near or to the emergency exits in the facility to guide a safe route to the emergency exits. The induction lamps 141a to 141n may each have only one direction indication, but may also have a plurality of direction indications 211 and 221 as shown in FIG. 2. When the induction lamp 151a has two direction indicators 211 and 221 as shown in FIG. 2, the guide lamp 151a is installed in two places separated in length as shown in FIG. 3. In the case where the induction lamp 151a has three direction marks, it is installed at a location divided into three lengths. In other words, one direction sign indicates one way to the emergency exit.

Referring to FIG. 3, when a fire occurs on the left side, the left direction indication 211 of the induction lamp 151a is turned off, and only the right direction indication 221 is turned on. Therefore, the evacuator can reach the emergency exit which is not affected by the fire by following the passage to the right, and can safely evacuate from the fire. On the contrary, when a fire occurs on the right side, the right direction display 221 of the induction lamp 151a is turned off, and only the left direction display 211 is turned on. If a fire occurs in both left and right sides, both the left direction display 211 and the right direction display 221 are turned off. At this time, the evacuator can avoid the fire by returning to the road he came from.

The plurality of power line communication units 131a to 131n are connected to the plurality of power lines 121 and the plurality of induction lamps 141a to 141n. The plurality of power line communication units 131a to 131n operate by receiving power from the power lines 121 and control the operations of the induction lamps 141a to 141n. The plurality of power line communication units 131a to 131n adjust the operations of the induction lamps 141a to 141n by receiving a fire signal from a fire detector located in a place where a fire has occurred or by receiving a command from the power line monitoring unit 111. Here, the plurality of power line communication units 131a to 131n are connected to power lines 122 before and after the plurality of auxiliary switching elements 133a to 133n. By doing so, power is stably supplied to the plurality of power line communication units 131a to 131n initially. That is, when no abnormality occurs in the power lines 122, power is supplied from the first section L1 to the last section Ln + 1, and only when the abnormality occurs in a specific section. Power is supplied at both ends. In addition, since the plurality of auxiliary switching elements 133a to 133n are all in an off state before power is supplied to the power lines 122, a plurality of induction controllers may be used to initially supply power to the power lines 122. The auxiliary switching elements 133a to 133n are sequentially turned on by the 421s of FIG. 4 to supply power to the power lines 122 in all sections. Power line communication units 131a to 131n will be described in detail with reference to FIG. 4.

The power line monitoring unit 111 is connected to both ends of the plurality of power lines 122. The power line monitoring unit 111 communicates with the plurality of power line communication units 131a to 131n, and monitors whether there is an abnormality of the power lines 122, and sequentially detects power for each of the plurality of sections when an abnormality is detected. And detecting a section in which an abnormality occurs while supplying in reverse order, cuts power to the section in which the abnormality occurs, and supplies power to all sections in which the abnormality has not occurred. The power line monitoring unit 111 receives power from a plurality of other power lines 121.

The power line monitoring unit 111 includes a first monitoring unit 251, a second monitoring unit 261, and a line controller 171.

The first monitoring unit 251 is connected to one end of the power lines 122 to detect an abnormal state of the power lines 122. The first monitoring unit 251 includes a first main switching element 253, a first main current detector 254, and a first image current transformer 256.

The first main switching element 253 is connected to the power lines 122 and is turned on or off under the control of the line controller 171. When the first main switching element 253 is on, power is sequentially supplied to the plurality of power line communication units 131a to 131n through the power lines 122, and when the first main switching element 253 is off, the plurality of power lines No power is supplied to the communication units 131a to 131n. The first main switching element 253 is preferably composed of a magnetic contact.

The first main current detector 254 is connected between the first main switching element 253 and the first power line communication unit, that is, the first section L1 of the power lines 122, and detects a current amount of the power lines 122. To the line controller 171.

The first image current transformer 256 is commonly connected to the power lines 122 between the first main switching element 253 and the first power line communication unit to detect a current difference between the power lines 122 to detect the line controller 171. To send.

The second monitoring unit 261 is connected to the other ends of the power lines 122 to detect an abnormal state of the power lines 122. The second monitoring unit 261 includes a second main switching element 263, a second main current detector 264, and a second image current transformer 266.

The second main switching element 263 is connected to the power lines 122 and is turned on or off under the control of the line controller 171. When the second main switching element 263 is turned on, power is supplied to the plurality of power line communication units 131a to 131n in reverse order through the power lines 122, and when the second main switching element 263 is turned off, the plurality of power lines No power is supplied to the communication units 131a to 131n. The second main switching element 263 is maintained in the off state when there is no abnormality in the power lines 122. Therefore, when there is no abnormality in the power lines 122, power is supplied to the power lines 122 only through the first main switching element 253, and the power lines 122 through the second main switching element 263. Power is not supplied to The second main switching element 263 is preferably composed of a magnetic contact.

The second main current detector 264 is connected to the power lines 122 between the second main switching element 263 and the n-th power line communication unit 131n to detect a current amount of the power lines 122 to detect the line controller 171. To send.

The second image current transformer 266 is commonly connected to the power lines 222 between the second main switching element 263 and the n-th power line communication unit 131n to detect a current difference between the power lines 222 to detect the line controller. Transmit to 171.

The line controller 171 is connected to the power lines 121, the first monitoring unit 251, and the second monitoring unit 261, receives power from the power lines 121, and supplies power through the power lines 121 and 122. Communication with the power line communication units 131a to 131n. The line controller 171 detects an abnormality of the power lines 122 while sequentially supplying power to the plurality of sections LL1 to LLn + 1 through the first monitoring unit 251, and detects the abnormality of the power lines 122. The power line 122 is detected by abnormally supplying power to the plurality of sections LL1 to LLn + 1 in the reverse order through 261. When an abnormality is detected, the line controller 171 cuts the power only to the section in which the abnormality occurs, and supplies power to all the sections in which the abnormality has not occurred. That is, the line controller 171 may output the output signals of the first main current detector 254 and / or the second main current detector 264 and the first image current transformer 256 and / or the second image current transformer 266. The output signal is received to determine whether there is an abnormality of the power lines 122, and when an abnormality of the power lines 122 is detected, the first main switching element 253 and / or the second main switching within a set time, for example, 0.03 seconds. After the element 263 is turned off, the plurality of sections LL1 to LLn are turned on after the first main switching small element 253 and / or the second main switching element 263 are turned on to find the section in which the abnormality has occurred. While supplying power to the power lines 122 of +1) sequentially or in reverse order, a section in which the abnormality occurs is detected.

4 is a detailed block diagram of one of the plurality of power line communication units 131a to 131n of FIG. 1 connected to the power lines 122. Referring to FIG. 4, the power line communication unit 131a includes an auxiliary switching element 411, an induction controller 421, a power supply unit 431, and a rechargeable battery 441.

The auxiliary switching element 411 switches adjacent power lines 122. The auxiliary switching element 411 is turned on or off under the control of the induction controller 421. Power is supplied to the power lines 122 when the auxiliary switching element 411 is turned on, and power is not supplied to the power lines 122 when the auxiliary switching element 411 is turned off. The auxiliary switching element 411 is turned off immediately after the power supplied to the power line communication unit 131a is cut off, and needs to be instructed by the induction controller 421 to be turned on again. The auxiliary switching element 411 may be configured of a relay, a silicon controlled rectifier, a triac, or the like.

The induction controller 421 includes an induction light driver 423, a switching device driver 425, and a power line transceiver 427. The induction lamp driver 423 controls the driving of the induction lamp (151a of FIG. 2) by receiving a fire signal from a fire detector located at a location where a fire occurs or receiving an instruction from the power line monitoring unit 111. The induction light driver 423 operates by receiving power from the rechargeable battery 441 when the power is disconnected from the power supply unit 431, but drives the direction indications (211 and 221 in FIG. 2) of the induction lamp (151a in FIG. 2) as before. do. The switching device driver 425 drives the auxiliary switching device 411 to be turned on under the instruction of the power line monitoring unit 111. The power line transceiver 427 exchanges data with the power line monitor 111 through the power lines 122.

When there is only one direction indicator of the induction lamp (151a in FIG. 2), the induction controller 421 normally turns on the direction indicator, and the current direction of the induction lamp when the fire signal is received from a fire detector located in a place where a fire has occurred. If the indication is checked and the direction indication is pointing to the emergency exit located at the place where the fire has occurred, the direction indication is turned off, otherwise it is kept lit. When there are two direction indicators of the induction lamp (151 a in FIG. 2), the induction controller 421 normally lights both of the direction indicators, and when the fire signal is received, indicates the emergency exit located at the place where the fire has occurred. The display is turned off, and the direction indication indicating the emergency exit located at the place where the fire has not occurred is kept lit.

The rechargeable battery 441 normally receives power supplied from the power lines 122 and is kept in a charged state. When the power is cut off, the rechargeable battery 441 supplies power to the induction controller 421 to cause the induction controller 421 to supply the induction lamp. Control the operation.

Referring to Figure 4 will be described with respect to the operation of the 101 shown in Figure 1 when a fire occurs. When a fire occurs, a fire detector installed in the place where the fire occurs outputs a fire signal and transmits it to all the power line communication units 131a to 131n. Upon receiving the fire signal, the power line communication unit immediately transmits the contents to the power line monitoring unit 111, and the power line monitoring unit 111 transmits the contents to the control center 181 through the wireless, wired or power lines 121. To pass. The control center 181 may reduce the casualty damage by notifying the people in the facility of the fire contents through an alarm device (not shown). The power line communication units 131a to 131n receiving the fire signal drive the direction indications of the induction lamps 141a to 141n connected thereto to indicate a way to an emergency exit located where no fire occurs. At this time, the power line monitoring unit 111 monitors whether there is an abnormality of the power lines 122, and if an abnormality occurs, the power line is detected and the power is supplied to all sections except for the section. The control center 161 is notified.

A method of detecting the abnormality of the power lines 122 by the line controller 171 of the line monitoring unit 111 will be described. If an error occurs in the power lines 122, the power line communication units 131a to 131n and the fire detectors 151a to 151m do not operate normally. If an error occurs in the power lines 122, the error is quickly detected and repaired. It is desirable to.

Abnormal states of the power lines 122 include a short circuit, a short circuit, a disconnection.

First, a description will be given of how the line controller 171 detects a short circuit of the power lines 122. Initially, the line controller 171 turns on the first main switching element 153 and turns off the second main switching element 163 to supply power to the power lines 122. At this time, the first image current transformer 156 compares the amount of current of each of the power lines 122, detects the difference, and transmits the difference to the line controller 171. The line controller 171 receives the output signal of the first current transformer 156, and if there is no difference in the amount of current between the power lines 122, determines that there is no short circuit in the power lines 122, and the difference in the amount of current If the level is higher than or equal to a predetermined level, it is determined that a short circuit exists in the power lines 122. The line controller 171 maintains the first main switching element 153 in an on state and the second main switching element 163 in an off state if there is no short circuit in the power lines 122, and a short circuit occurs in the power lines 122. If it is determined that the first main switching device 153 is turned off within a predetermined time, for example, 0.03 seconds. When the first main switching element 153 is turned off, power supply to the power lines 122 is cut off, so that the plurality of power line communication units 131a to 131n do not operate either. As a result, all of the auxiliary switching elements 133a to 133n provided in the plurality of power line communication units 131a to 131n are turned off. When the auxiliary switching elements 133a to 133n are all turned off, power is not supplied to the power lines 122 of all the sections L1 to Ln + 1.

The line controller 171 turns on the first main switching element 153 to find the ground fault position. When the first main switching element 153 is turned on, power is supplied to the power lines 122 and the first power line communication unit 131a in the first section L1. At this time, the line controller 171 receives the output signal of the first current transformer 156 and determines whether there is a short circuit of the power lines 122 in the first section L1. If there is a short circuit in the first section L1, the line controller 171 turns off the first main switching element 153 within a set time, for example, 0.03 seconds, and then, in the control section 181, the first main section L1 is turned off. Notify that a short circuit has occurred. If there is no short circuit in the first section L1, the line controller 171 turns on the auxiliary switching device 133a of the first power line communication unit 131a while keeping the first main switching device 153 in the on state. Makes a command. Accordingly, power is supplied to the power lines 122 and the second power line communication unit 131b in the second section L2. In this state, the line controller 171 receives the output signal of the first current transformer 156 and determines whether there is a short circuit of the power lines 122 in the second section L2. If there is a short circuit in the second section L2, the first main switching device 153 is turned off and the control center 181 is notified that a short circuit has occurred in the second section L2, and then the first main switching device ( 153 is turned on to supply power to the power lines 122 of the first section L1. At this time, since the auxiliary switching element 133a of the first power line communication unit 131a is turned off, power is not supplied to subsequent power lines 122 including the second section L2. If there is no short circuit in the second section L2, the process proceeds to the last section Ln + 1. Therefore, it is possible to find out the section in which the short circuit occurs, the power is cut off from the section after the short circuit occurs, and the power is supplied to the section before the short circuit.

As such, when a section in which a short circuit occurs is detected, the line controller 171 allows power to be supplied to power lines in the remaining sections except the section in which the short circuit occurs through the second monitoring unit 161. That is, since the line controller 171 already knows where the leakage occurs, through the process, power is supplied in the reverse order to the section before the leakage occurs through the second monitoring unit 161. If a second leakage occurs in another area between the section where the leakage occurs and the second monitoring unit 161, the line controller 171 reverses the section where the secondary leakage occurs in the reverse order as follows. Detect. When the second short circuit occurs, the second main switching element 163 is turned off. Accordingly, the line controller 171 turns on the second main switching element 163 to supply power to the power lines 122 and the n-th power line communication unit 231n in the (n + 1) th section. At this time, the line controller 171 receives the output signal of the second image current transformer 166 and determines whether there is a short circuit of the power lines 122 in the (n + 1) th section Ln + 1. If there is a short circuit in the (n + 1) th section Ln + 1, the line controller 171 turns off the second main switching element 163 within a set time, for example, 0.03 seconds, and stops all the progress. Therefore, power is not supplied to the (n + 1) th section Ln + 1 from this point on. If there is no short circuit in the (n + 1) th section (Ln + 1), the line controller 171 transmits the auxiliary switching element to the nth power line communication unit 231n while keeping the second main switching element 163 on. Command to turn on (233n). Accordingly, power is supplied to the power lines 122 and the (n-1) th power line communication unit 131n-1 in the nth section Ln. In this state, the line controller 171 receives the output signal of the second image current transformer 166 and determines whether there is a short circuit of the power lines 122 in the n-th section Ln. If there is a short circuit, the line controller 171 instructs the n-th power line communication unit 131n to turn off the auxiliary switching element 133n. Therefore, power is cut off in the n-th section Ln, and power is supplied to subsequent power lines 122 including the n-th section Ln. If there is no short circuit in the nth section Ln, the process is performed for the preceding sections.

In this manner, the section in which the short circuit occurs can be detected immediately, and the power supply is cut off only in the power lines 122 in the section in which the short circuit occurs, and power is supplied to the power lines 122 in all sections in which the short circuit does not occur. . Therefore, it is possible to reduce the time loss required to find the section in which the short circuit has occurred, and also to reduce the physical loss by continuously supplying electric power to all sections in which the short circuit has not occurred.

Next, a description will be given of how the line controller 171 detects a short circuit of the power lines 122. Short circuit means that the power lines 122 are interconnected. Initially, the line controller 171 turns on the first main switching element 153 and turns off the second main switching element 163 to supply power to the power lines 122. Then, the first main current detector 154 detects the amount of current flowing through the power lines 122 and transmits it to the line controller 171. The line controller 171 inputs an output signal of the first main current detector 154 to check the magnitude of the current flowing through the power lines 122. At this time, the line controller 171 determines that the power lines 122 are not short-circuited if the magnitudes of the currents flowing through the power lines 122 are within the set range, and the magnitudes of the currents flowing through the power lines 122 are set. If it is over the range, the power lines 122 are determined to be shorted. The line controller 171 keeps the first main switching element 153 on when the power lines 122 are not shorted, and immediately turns off the first main switching element 153 when the power lines 122 are shorted. Turn it off. When the first main switching element 153 is turned off, power supply to the power lines 122 is cut off, so that the plurality of power line communication units 131a to 131n do not operate either. As a result, the auxiliary switching elements 133a to 133n provided in the plurality of power line communication units 131a to 131n are all turned off, so that power is not supplied to the power lines 122 in all sections L1 to Ln + 1.

When the internal power lines 122 are shorted, the line controller 171 immediately proceeds to find a shorted section. The process of detecting the shorted sections of the internal power lines 122 by the line controller 171 is similar to the process of detecting the shorted sections, and thus redundant description thereof will be omitted.

In conclusion, the line controller 171 can immediately find the section in which the short circuit occurs, and the power is not supplied to the section in which the short circuit occurs, and the power lines 122 in all sections L1 to Ln where the short circuit has not occurred. Allow the power to continue. Therefore, the time loss to find the section where the short circuit has occurred is reduced, and the physical loss can be reduced by continuing to supply power to all sections where the short circuit has not occurred.

In addition, a method of detecting the disconnection of the power lines 122 by the line controller 171 will be described. Disconnection means that one of the power lines 122 is broken. Initially, the line controller 171 turns on the first main switching element 153 to supply power to the power lines 122. Then, the first main current detector 154 detects the amount of current flowing through the power lines 122 and transmits it to the line controller 171. The line controller 171 inputs an output signal of the first main current detector 154 to check the magnitude of the current flowing through the power lines 122. At this time, if the magnitude of the current detected by the first main current detector 154 is within the set range, it is determined that the power lines 122 are not disconnected, and the current detected by the first main current detector 154 is within the set range. If less, the power lines 122 are determined to be disconnected. The line controller 171 maintains the first main switching element 153 on if the power lines 122 are not disconnected and are in a normal state. If the power lines 122 are disconnected, the line controller 171 disconnects the first main switching element 153. Turn it off. When the first main switching element 153 is turned off, power supply to the power lines 122 is cut off, so that the plurality of power line communication units 131a to 131n do not operate either. As a result, the auxiliary switching elements 133a to 133n provided in the plurality of power line communication units 131a to 131n are all turned off, so that power is not supplied to the power lines 122 in all sections L1 to Ln + 1.

When the internal power lines 122 are disconnected, the line controller 171 immediately proceeds to find the disconnected section. The process of detecting the disconnected sections of the power lines 122 by the line controller 171 is similar to the process of detecting the shorted sections, and thus redundant description thereof will be omitted.

As a result, the line controller 171 can immediately find the section in which the disconnection occurred, the power is not supplied to the section in which the disconnection occurred, and the power line 122 in all sections in which the disconnection does not occur continues to be powered. To be supplied. Therefore, the time loss in finding the section where the disconnection has occurred is reduced, and the material loss can be reduced by continuing to supply power to the power lines 122 in all sections where the disconnection has not occurred.

As described above, according to the present invention, when a fire occurs in a facility in which the evacuation induction system 101 is installed, the fire detectors 151a to 151m located near the fire detect the fire and output a fire signal. The power line communication units 131a to 131n transmit power to the power line communication units 131a to 131n, and the plurality of power line communication units 131a to 131n connect the direction indicators 211 and 221 of the induction lamps 141a to 141n connected thereto to emergency exits located where no fire occurs. Control to point the way. Therefore, people inside the facility move along the path guided by the induction lamps 141a to 141n, thereby minimizing the casualty damage caused by the fire. In particular, as underground facilities such as subways and underground shopping malls increase, and many people live in these spaces, the damage may be enormous in the event of a fire in such a place. By providing 101), the effect of preventing human damage can be greatly improved.

In addition, the line monitoring unit 111 always monitors whether there is an abnormality of the power lines 122 and supplies power to all other sections except the section where the abnormality occurs when the abnormality occurs in the power lines 122. Even though the fire detectors 151a to 151m and the power line communication units 131a to 131n where the fire does not occur are normally operated. Thus, induction lamps located in isolation from the fire will operate normally, resulting in minimal human and material damage.

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 (8)

delete In evacuation guidance system installed in the facility, A plurality of power lines for transmitting power; A plurality of fire detectors connected to the power lines for detecting a fire; A plurality of induction lights installed in the facility to guide the way to one or more emergency exits installed in the facility; An auxiliary switching element connected to the power lines to control a connection state of the power lines, an induction controller connected to the power lines and the auxiliary switching element and the induction lamp to control an operation of the auxiliary switching element and the induction lamp, and the induction And a power supply unit for supplying power to the controller, and when receiving a fire signal output from a fire detector detecting a fire among the plurality of fire detectors, controlling the induction lamps to direct a passage to an emergency exit which is not affected by the fire. A plurality of power line communication units; And A power line monitoring unit connected to both ends of the plurality of power lines; The plurality of power lines are divided into a plurality of sections, The power line monitoring unit monitors the abnormality of the power lines, and when an abnormality is detected, detects a section in which an abnormality occurs while sequentially supplying power to the plurality of sections, and supplies power in reverse order to the plurality of sections. Evacuation induction system characterized in that for detecting the section in which the abnormality occurs, the power is cut off in the section where the abnormality occurs, and supplying power to all the sections in which the abnormality has not occurred. The rechargeable battery of claim 2, further comprising: a rechargeable battery connected to the induction controller, which is supplied with power from the power lines and is kept in a charged state, and supplies power to the induction controller instead of the power unit when the power supply unit is stopped. Evacuation guidance system, characterized in that it further comprises. delete The method of claim 2, wherein the induction controller An induction light driver for driving the induction light; A switching element driver for driving the auxiliary switching element; And Evacuation guidance system comprising a power line transceiver for transmitting and receiving data with the power line monitoring unit. The power line monitoring unit of claim 2, wherein the power line monitoring unit A first monitoring unit connected to one end of the power lines to monitor an abnormality of the power lines; A second monitoring unit connected to the other ends of the power lines to monitor an abnormality of the power lines; And Connected to the first monitoring unit and the second monitoring unit in common, and detecting an abnormality of power lines arranged in the plurality of sections while supplying power to the plurality of sections sequentially through the first monitoring unit, While supplying power to the plurality of sections in reverse order through the second monitoring unit, it detects the presence or absence of power lines arranged in the plurality of sections, and when the abnormality is detected, cuts off power only to the section in which the abnormality occurs. And a line controller for supplying electric power to all sections in which the abnormality does not occur. The method of claim 6, wherein the first monitoring unit A first main switching element connected to one end of the power lines; A first main current detector connected to power lines between the first main switching element and a first power line communication unit of the plurality of power line communication units to detect a current amount of each of the power lines; And A first image current transformer connected to power lines between the first main switching element and the first power line communication unit to detect a current difference between the power lines; The second monitoring unit A second main switching element connected to the other ends of the power lines; A second main current detector connected to power lines between the second main switching element and the last power line communication unit of the power line communication units to detect a current amount of each of the power lines; And And a second image current transformer connected in common to power lines between the second main switching element and the last power line communication unit to detect a current difference between the power lines. 3. The evacuation guidance system of claim 2, further comprising a control center connected to the plurality of power lines, analyzing fire information transmitted from the plurality of fire detectors, and setting an evacuation route of the facility. system.

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