KR101623760B1 - Distribution board - Google Patents

Abstract

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a distribution board for quickly determining whether a fire occurs inside and / or outside a distribution panel by sensing an internal situation and / or an external situation of the distribution board.
Specifically, the present invention provides a power supply apparatus comprising: a main busbar to which power is supplied; A main breaker for selectively interrupting power supplied through the main busbar; A branch bus bar for supplying the power from the main breaker to each branch in accordance with each load via the main busbar in a distributed manner; A plurality of sub-circuit breakers connected to the branch bus bars for selectively blocking the distributed power delivered to the loads; A housing part for supporting or receiving the main busbar, the main circuit breaker, the branch busbar and the sub circuit breaker and forming an outer appearance; A camera module mounted on a front surface of the housing part, the camera module capturing an internal state and an external state of the housing part; And a control unit for controlling the main busbar, the main breaker, the branch bus bar, the sub-circuit breaker, and the camera module, wherein the control unit controls the main bus bar, And judging whether or not a fire has occurred inside or outside the housing part based on the data.

Description

DISTRIBUTION BOARD

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a distribution board, and more particularly, to a distribution board that detects the internal state and / or the external situation of a distribution board and quickly judges whether a fire occurs inside and /

In general, a distribution board is composed of a structure that attaches and supports unit devices such as a breaker or a protective relay, and a collection of conductors (bus bars, cables, etc.) connecting and connecting the unit devices. High pressure, high pressure, low pressure switchboard. The main circuit for transmitting electric power in the above-mentioned distribution panel is composed of a booth which is a conductor.

Such a bus bar is an electric part used for providing a power supply passage in a distribution board or the like.

In addition, the distribution board is usually installed in units of buildings, units, units of ships, and small-scale caterpillars. When a shipboard is placed in an unstable state by vibration or movement from time to time, The vibration or shock transmitted to the distribution panel causes mechanical tripping or malfunction of the circuit breaker, which has caused a disruption in the power supply in the ship.

In addition, when the distribution board is installed in a place where a large amount of high temperature and fine dust are generated, the distribution board is sealed as much as possible in order to prevent malfunction of the wiring breaker due to fine dust. At this time, The internal temperature suddenly rises, so that the circuit breaker installed inside the circuit breaker is deteriorated and the normal operation force is lost or exposed to the risk of fire.

Particularly, among the causes of fire events occurring in everyday life, surge power is supplied to the bus bar of the distribution board, or a considerable number of fire incidents due to the high temperature of the bus bar provided in the distribution board or the self- exist.

The conventional distribution board according to the related art is configured to prevent a fire in the distribution board only by a surge protector when a sudden voltage change occurs such as a surge power or the like, The fire inside the distribution panel due to the self heat generation and the fire at the installation site where the distribution panel is installed (ie outside the distribution panel) can not be detected at all. Therefore, in case of a fire event related to the distribution panel, There has been a problem that early fire can not be found around the fire.

It is therefore an object of the present invention to provide a distribution board for solving the problems of the prior art.

Specifically, it is an object of the present invention to provide a distribution board capable of early detection of a fire occurring both inside and outside of a distribution board.

It is still another object of the present invention to provide a distribution board for allowing a manager to easily recognize a fire inside and outside of a distribution board when a fire occurs.

According to one embodiment of the present invention, the present invention provides a power supply apparatus comprising: a main busbar to which power is supplied; A main breaker for selectively interrupting power supplied through the main busbar; A branch bus bar for supplying the power from the main breaker to each branch in accordance with each load via the main busbar in a distributed manner; A plurality of sub-circuit breakers connected to the branch bus bars for selectively blocking the distributed power delivered to the loads; A housing part for supporting or receiving the main busbar, the main circuit breaker, the branch busbar and the sub circuit breaker and forming an outer appearance; A camera module mounted on a front surface of the housing part, the camera module capturing an internal state and an external state of the housing part; And a control unit for controlling the main busbar, the main breaker, the branch bus bar, the sub-circuit breaker, and the camera module, wherein the control unit controls the main bus bar, And determining whether a fire occurs inside or outside the housing part based on the data.

Preferably, the camera module includes a first camera section for photographing an internal state of the housing section, and a second camera section for photographing an external state of the housing section.

Preferably, the camera module includes a first mounting part for accommodating the first camera part and a second mounting part for accommodating the second camera part, wherein the first mounting part and the second mounting part are arranged in a front-back direction And is integrated.

Preferably, the first mounting portion is formed to be inclined such that it is directed downward at a predetermined angle from the rear of the second mounting portion.

Preferably, the first camera unit is configured by an infrared camera.

Preferably, the first camera unit includes a wide-angle lens or a fish-eye lens.

Preferably, the control unit determines that a fire occurs when an image area in which a size change of a predetermined size or larger is detected among a plurality of image areas included in the internal image data and the external image data of the housing unit exists .

Preferably, the control unit determines that a fire occurs only when a change in size of the predetermined size or larger is detected for a predetermined time or longer in an image area where a change in size over the predetermined size is detected.

Preferably, the control unit determines that a fire occurs when an image area in which a light amount change of a predetermined light amount or more is detected among a plurality of image areas included in the internal image data and the external image data of the housing part, .

Preferably, the control unit determines that a fire is generated only when a change in the amount of light at a predetermined light amount or more is detected for a predetermined time or longer in an image region where a light amount change over a predetermined light amount is detected.

Preferably, the controller controls the main breaker to shut off power supplied directly to the sub-booth from the main booth bar when it is determined that a fire has occurred inside or outside the housing part.

Preferably, the distribution board further includes a communication module capable of performing data communication with a terminal of an administrator of the distribution board. When the controller determines that a fire has occurred inside or outside the housing part, To the terminal of the manager.

Preferably, the distribution board further includes a memory module, and the controller stores the internal image data and the external image data of the housing part in the memory module in real time.

Preferably, the memory module is housed in a protective case made of a flammable material.

According to the above-mentioned problem solving means, the present invention can detect a fire occurring in both the inside and the outside of the distribution panel in an early stage by monitoring the internal state and the external state of the distribution board in real time by using the camera module, A fire inside the distribution board due to the high temperature of the booth bar or self heat generation can be detected early.

In addition, the present invention analyzes internal image data and external image data of a distribution panel photographed through a camera module to determine whether or not a fire has occurred, so that it is possible to more quickly and accurately determine whether a fire has occurred, It is possible to prevent an expansion in a large fire early.

Further, the present invention can quickly transmit the occurrence of a fire to a terminal of an administrator when a fire occurs inside or outside the distribution panel by providing a communication module, so that the manager can quickly and easily recognize the occurrence of a fire inside or outside the distribution panel .

1 is a schematic external perspective view of a distribution board according to an embodiment of the present invention.
2 is a schematic block diagram of a distribution board according to an embodiment of the present invention.
3 is a schematic internal configuration diagram of a distribution board according to an embodiment of the present invention.
4 is a schematic cross-sectional view of a distribution board according to line AA of FIG.
5 is a schematic vertical cross-sectional view of a distribution board according to the BB line of FIG.
FIG. 6 is a schematic longitudinal sectional view of a distribution board according to another embodiment of the present invention, taken along line BB of FIG. 1;

Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings so that those skilled in the art can easily carry out the present invention. It should be noted that the drawings denoted by the same reference numerals in the drawings denote the same reference numerals whenever possible, in other drawings. In the following description of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear. And certain features shown in the drawings are to be enlarged or reduced or simplified for ease of explanation, and the drawings and their components are not necessarily drawn to scale. However, those skilled in the art will readily understand these details.

FIG. 1 is a schematic external perspective view of a distribution board 1000 according to an embodiment of the present invention. FIG. 2 is a schematic internal structure diagram of a distribution board 1000 according to an embodiment of the present invention, Is a schematic block diagram of a distribution board 1000 according to an embodiment of the present invention,

1 to 3, a distribution board 1000 according to an embodiment of the present invention includes a main bus bar 110, a main breaker 130, a plurality of branch bus bars 140, A plurality of sub-circuit breakers 150, a housing unit 200, a camera module 300, a control unit 170, a memory module 191, a communication module 193 and the above- And a housing part 200 accommodating the housing part 200.

2, the distribution board 1000 includes a main bus bar 110, a watt hour meter 120 for detecting the amount of power supplied through the main bus bar 110, A main circuit breaker 130 for selectively interrupting the power supplied through the watt hour meter 120 and a main circuit breaker 130 for controlling the user's convenience A plurality of sub-circuit breakers 150 connected to the branch bus bars 140 to selectively block the distributed power transmitted to each load, A current detector 160 for detecting a current in the branch bus bar 140 through which the distributed power is output through each of the sub-circuit breakers 150, and a current detector 160 for detecting information transmitted through the current detector 160 Acceptance of quarterly power abnormality And a meter transformer 180 configured to detect a disturbance (Sag, Swell, Swing, etc.) of a voltage flowing in the main bus bar 110, which is provided in the controller 170, do.

The distribution board 1000 according to the present invention may be a DC power distribution board 1000 or an AC power distribution board 1000. [ Hereinafter, for the sake of clarity, only the case where the distribution board 1000 is an AC power distribution board 1000 will be described. However, it is a matter of course that the distribution board 1000 is applicable to the AC power distribution board 1000 as well.

The main busbar 110 of -190V 380V _DC and + 190V _DC And supplies the power to the inside of the distribution panel 1000.

At this time, the watt-hour meter is configured to detect a DC power amount, and the current detecting unit is configured to detect a DC current in the branch bus bar 140 where DC power is output through each of the sub-circuit breakers 150.

Here, the result of determining whether there is a power abnormality for each branch through the controller 170 is transmitted and stored in real time to the administrator or the user terminal T (for example, a desktop PC, a tablet PC, a smart phone or the like) When it occurs, it provides service such as letter to manager.

The information detected by the current detector 160 is branched and transmitted to the controller 170. The analyzed result of the controller 170 is transmitted to the terminal T via the Mod-Bus, Is displayed on the screen.

If the controller 170 detects an error based on the information stored in the terminal T, the controller 170 transmits the status of the distribution panel 1000 to the administrator using TCP / IP or the Internet.

In the present invention configured as described above, a DC voltage (DC) is drawn through a power company and a rectifier, electric power is delivered to the main bus bar 110 through a DC watt hour meter for power consumption and a main breaker 130, A power meter 120, a plurality of breakers (MCCB or earth leakage breaker) 150, a current detector 160, and a controller 140. The main bus bar 110, the watt- The DC current transmitted to the branch bus bar 140 through the main bus bar 110 is detected through a current detector 160 provided for each branch and the DC voltage is detected by the controller 170. [ And is detected through the built-in instrument transformer 180.

Each of the branch currents detected by the current detector 160 provided for each of the branch bus bars 140 is collected by the controller 170. The currents of the branches collected in the controller 170 and the pre- And determines whether there is a power abnormality in each of the branch bus bars 140.

In addition, disturbances (Sag, Swell, Swing, etc.) of the DC voltage flowing through the main bus bar 110 are detected through the instrument transformer 180 built in the controller 170 and compared with the set reference voltage value, Determines whether there is an abnormality in the electric power flowing in the main bus bar (110), and supplies high quality direct current power.

Then, the information analyzed through the controller 170 is transmitted to the terminal T of the manager through the ModBus, and the terminal T of the manager transmits the DC voltage to the main bus bar 110 in real time, By displaying the state of the direct current flowing in the battery 140.

When the over-current or over-voltage occurs in the main bus bar 110 or the branch bus bar 140 while monitoring the real time through the terminal T of the manager, the over-current or over-voltage is delivered to the manager via TCP / So that they can cope.

Therefore, the distribution board 1000 capable of monitoring the (direct current) power according to the present invention outputs the currents and voltages obtained in real time through the current detecting unit 160 installed in each branch and the instrument transformer 180 built therein to the controller 170), it is possible to analyze the correlation between the voltage and the current in the no-load state and the rated state, process it according to the calculation, confirm the power quality, and supply the high-quality power to the consumer.

Accordingly, an accident caused by an overcurrent or an overvoltage of the distribution board 1000 installed in a building or a factory can be prevented in advance, thereby reducing electrical fire accidents and personal injury.

The housing part 200 includes the main bus bar 110, the main breaker 130, the branch bus bar 140, the camera module 300, the controller 170, the memory module 191 ), The communication module 193 and the sub-circuit breaker 150, and forms an outer appearance of the minute front side.

The housing part 200 includes a housing main body 210 defining a receiving space and a front cover part 220 rotatably provided at a front part of the housing main body 210.

The housing body 210 has a front rim portion 211 for supporting the front lid portion 220.

A camera module 300 for photographing the internal state and the external state of the housing unit 200 is installed in a front part (for example, a front frame part 211) of the housing part 200. The camera module 300 transmits internal image data and external image data of the photographed housing unit 200 to the controller 170.

The control unit 170 determines whether a fire has occurred inside or outside the housing unit 200 based on internal image data and external image data of the housing unit 200 photographed through the camera module 300 .

By monitoring the internal state and the external state of the distribution panel 1000 in real time using the camera module 300 in this way, it is possible to detect a fire occurring in both the inside and the outside of the distribution panel 1000 at an early stage, A fire in the distribution board 1000 due to the high-temperature phenomenon of the booth bar or the self heat generation of the booth bar 1000 installed in the boiler room 1000 can be detected early.

When the controller 170 determines that a fire has occurred inside and / or outside the housing unit 200 based on the internal image data and the external image data of the housing unit 200, The sub-circuit breaker 150 and the communication module 193 to turn on / off the power supply to the main busbar 110 and the branch busbar 140, To the terminal (T).

The fire detection of the controller 170 using the camera module 300 and the control algorithm thereafter will be described in more detail with reference to the following drawings.

4 is a schematic cross-sectional view of a distribution board taken along line A-A of Fig.

5 is a schematic vertical cross-sectional view of a distribution board taken along the line B-B in Fig.

FIG. 6 is a schematic vertical sectional view of a distribution board according to another embodiment of the present invention, taken along line B-B of FIG. 1;

4 and 5, the camera module 300 is installed to penetrate the front edge portion 211 of the housing portion 200, and the internal and external states of the distribution board 1000 And is configured to shoot in real time. The camera module 300 is always connected to a power source.

Specifically, the camera module 300 includes a first camera unit 310 for photographing the internal state of the housing unit 200, a second camera unit 320 for photographing the external state of the housing unit 200, .

The first camera unit 310 is accommodated in a first mounting portion 315 and the internal state of the distribution board 1000 which is condensed through the first lens 311 and the first lens 311 is referred to as an electrical image And a first image sensor 313 for converting the image signal into a data signal. That is, the first lens 311 and the first image sensor 313 are supported and received by the first mounting portion 315.

Preferably, the first camera unit 310 may be an infrared camera. This is because the panel 1000 generally operates in a state in which the front lid 220 is closed so that the inside of the panel 1000 is in a state similar to the dark room, It is possible to improve the fire detection accuracy by configuring the first camera unit 310 as an infrared camera.

Also, preferably, the first lens 311 may be a wide-angle lens or a fisheye lens. This is because the first lens 311 is directed to the inside of the panel 1000 and the distribution panel 1000 has a limited distance from the front edge 211 to the rear portion so that the first lens 311 The main bus bar 110, the branch bus bar 140, the main breaker 130 and the sub circuit breaker 150 of the distribution board 1000 are all photographed. That is, by configuring the first lens 311 with a wide-angle lens or a fisheye lens, the inside of the distribution board 1000 can be photographed without a blind spot, thereby improving the fire detection accuracy.

The second camera unit 320 is accommodated in the second mounting unit 325 and the internal state of the distribution board 1000 which is condensed through the second lens 321 and the second lens 321 is displayed as an electrical image And a second image sensor 323 for converting the image signal into a data signal. That is, the second lens 321 and the second image sensor 323 are supported and received by the second mounting portion 325.

The first image sensor 313 and the second image sensor 323 are formed of a CCD (Charge Coupled Device) or a CMOS (Complementary Metal-Oxide Semiconductor).

4 and 5, the first mounting portion 315 and the second mounting portion 325 are integrally formed in the front and rear direction, and the first mounting portion 315 and the second mounting portion 325 are integrally formed, The second mounting portion 325 is configured such that the first lens 311 and the second lens 321 face each other in the opposite direction.

As shown in FIG. 6, the first mounting portion 315 is formed so as to be inclined from the rear of the second mounting portion 325 toward a downward direction at a predetermined angle. That is, the first mounting portion 315 is coupled to and formed on the second mounting portion 325 such that the photographing angle of the first lens 311 is directed in the lower oblique direction. The main bus bar 110, the branch bus bar 140, the main breaker 130 and the branch breaker are disposed generally in the middle or in the lower part of the inside of the distribution board 1000 and in the upper part of the distribution board 1000, The main bus bar 110, the branch bus bar 140, the main breaker 130, and the main circuit breaker 140, except for the upper part inside the panel board 1000, which is an unnecessary photographing area, ) And the critical monitoring part where the branch circuit breaker is placed.

A memory module 191 is provided on the inner surface of the front edge 211 of the distribution board 1000. The memory module 191 stores the states of the distribution panel 1000 photographed by the camera module 300.

The memory module 191 includes a memory socket 191a and a memory card 191b and the memory card 191b is connected to the memory socket 191a by an SD card Digital card).

Preferably, the memory module 191 may be housed in a protective case made of a flammable material. Since the memory module 191 serves as a kind of black box as will be described later, the memory module 191 stores important data necessary for identifying the cause of the fire in the inside and outside of the distribution board 1000, So as not to be damaged.

A communication module 193 is provided on the upper portion of the housing part 200. The communication module 193 receives a control signal from the terminal T of the manager and transmits the control signal to the controller 170 so that the manager The main breaker 130 and the sub circuit breaker 150 can be remotely controlled through the terminal T of the own terminal.

Hereinafter, a control algorithm for detecting and determining whether or not a fire has occurred inside and / or outside the distribution board 1000 and a subsequent control algorithm for the controller 170 at the time of fire occurrence will be described in detail Will be described.

First, the controller 170 drives the first camera unit 310 and the second camera unit 320 of the camera module 300. The first camera unit 310 and the second camera unit 320 photograph the internal state and the external state of the housing unit 200 in real time and transmit the internal image data of the housing unit 200 and the external image And transmits the generated data to the control unit 170.

The control unit 170 stores the internal image data and the external image data of the housing unit 200 in the memory module 191 in real time. Preferably, the internal image data and the external image data of the housing unit 200 taken by the camera module 300 are stored in the memory module 191, Data and external image data are transmitted to a management server (not shown) through a communication module 193 and stored in the management server, and the memory module 191 deletes the internal image data and external image data of the predetermined capacity So that the memory capacity can be secured.

If there is an image area in which a change in size over a predetermined size is detected from a plurality of image areas included in the internal image data and the external image data of the housing part 200, do.

That is, for example, when smoke or flame is generated due to overheating in the sub-circuit breaker 150, the control unit 170 controls the sub-circuit breaker 150 such that smoke or flame is generated in the image area where the sub- Is set as one reference value. In the image region where the sub-breaker 150 is located before the fire occurs, due to smoke or flame spreading or spreading in the image area where the sub-circuit breaker 150 is positioned after the smoke or flame is generated, The control unit 170 determines that a fire has occurred inside the distribution board 1000. In this case,

Preferably, the control unit 170 determines that a fire is generated only when a change in size of the smoke or flame having a predetermined size or larger is detected, and at the same time, a change in size over the predetermined size is detected for a predetermined time . This is because temporary smoke is generated in the main booth bar 110, the branch booth bar 140, the main breaker 130 or the sub circuit breaker 150 and then the interior of the distribution board 1000 is quenched, This is because it is impossible to recognize the manager until the end of the fire.

That is, the controller 170 determines whether or not a fire has occurred by considering control variables of two conditions, that is, a size change over a predetermined size in a specific image area, It is possible to more accurately determine whether or not the fire has occurred, and at the same time, the fire management efficiency of the manager can be improved.

If there is an image area in which a light quantity change of a predetermined light quantity or more is detected among a plurality of image areas included in the internal image data and the external image data of the housing part 200, .

That is, for example, when smoke or flame is generated due to overheating in the sub-breaker 150, the controller 170 controls the sub-breaker 150 in the image area where the sub-breaker 150 is located before the smoke or flame is generated The amount of light emitted from the sub-circuit breaker 150 due to the smoke or flame in the image area where the sub-circuit breaker 150 is located after the generation of smoke or flame is set to a predetermined amount, (When a spark occurs) or becomes smaller (when a smoke is generated) than the amount of light of the sub-circuit breaker 150 before the occurrence of a fire (i.e., a preset light amount) 1000) is inside the fire.

Preferably, the control unit 170 may determine that a fire has occurred only when a change in the amount of light over the predetermined light amount is detected for a predetermined time or longer in an image region where a light amount change over a predetermined light amount is detected.

This is because smoke or flame occurs in the main booth bar 110, the branch booth bar 140, the main breaker 130 or the sub circuit breaker 150 due to temporary overheating, and then the inside of the distribution board 1000 is quenched, This is because fire can not be avoided and it can be canceled. Also, it is because management's efficiency is deteriorated by letting the manager recognize the fire until the end of the fire.

That is, the controller 170 determines whether or not a fire has occurred by considering control variables of two conditions, that is, a light amount change detection over a preset light amount and a light amount change over a predetermined light amount, It is possible to more accurately determine whether or not the fire has occurred, and at the same time, the fire management efficiency of the manager can be improved.

When the controller 170 determines that a fire has occurred inside or outside the housing 200, the controller 170 controls the main breaker 130 to shut off the power supplied from the main booth bar 110 to the sub- Can be controlled. Of course, when the controller 170 determines that a fire has occurred inside or outside the housing unit 200, the controller 170 controls the sub-circuit breaker 150 to shut off the distributed power supplied to the load from the branch busbar 140, Can be controlled.

The control unit 170 may detect a fire occurrence of the distribution board 1000 through the communication module 193 when a fire occurs inside or outside the housing unit 200, T).

According to the present invention, the camera module is used to monitor the internal and external states of the distribution panel in real time, so that it is possible to detect a fire occurring both inside and outside of the distribution panel early, Fire inside the distribution panel due to high temperature of the bar or self heat can also be detected early.

In addition, the present invention analyzes internal image data and external image data of a distribution panel photographed through a camera module to determine whether or not a fire has occurred, so that it is possible to more quickly and accurately determine whether a fire has occurred, It is possible to prevent an expansion in a large fire early.

Further, the present invention can quickly transmit the occurrence of a fire to a terminal of an administrator when a fire occurs inside or outside the distribution panel by providing a communication module, so that the manager can quickly and easily recognize the occurrence of a fire inside or outside the distribution panel .

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, . ≪ / RTI > Accordingly, such modifications are deemed to be within the scope of the present invention, and the scope of the present invention should be determined by the following claims.

1000: Distribution board
110: Main booth bar
130: main breaker
140: Branch booth bar
150: Sub-
300: camera module
310: first camera section
320:

Claims (14)

A main bus bar to which power is supplied;
A main breaker for selectively interrupting power supplied through the main busbar;
A branch bus bar for supplying the power from the main breaker to each branch in accordance with each load via the main busbar in a distributed manner;
A plurality of sub-circuit breakers connected to the branch bus bars for selectively blocking the distributed power delivered to the loads;
A housing part for supporting or receiving the main busbar, the main circuit breaker, the branch busbar and the sub circuit breaker and forming an outer appearance;
A first camera unit provided on a front surface of the housing unit and configured to photograph an internal state of the housing unit so as to capture an internal state and an external state of the housing unit; and a second camera unit configured to photograph an external state of the housing unit, A first mounting portion for accommodating the first camera portion and a second mounting portion for accommodating the second camera portion, wherein the first mounting portion and the second mounting portion are integrally formed in the front and rear direction, A camera module formed to be inclined from a rear side of the second mounting portion toward a downward direction at a predetermined angle;
And a controller for controlling the main busbar, the main breaker, the branch busbar, the sub-circuit breaker, and the camera module,
Wherein the control unit determines whether a fire occurs inside or outside the housing unit based on the internal image data and the external image data of the housing unit photographed through the camera module and is included in the internal image data and external image data of the housing unit Wherein when the image region is detected from an image region of a smoke or flame having a size set to one reference value among a plurality of image regions to which a reference value is set, And judging that a fire has occurred when a change in size over a size set as a reference value is detected for a time set as a reference value. delete delete delete The method according to claim 1,
Wherein the first camera unit comprises an infrared camera. The method according to claim 1,
Wherein the first camera unit comprises a wide-angle lens or a fish-eye lens. delete delete The method according to claim 1,
Wherein the control unit determines that a fire occurs when an image area in which a light quantity change of a predetermined light quantity or more is detected among a plurality of image areas included in the internal image data and the external image data of the housing unit is present. 10. The method of claim 9,
Wherein the controller determines that a fire occurs only when a change in light quantity of the predetermined amount of light or more is detected for a predetermined time or longer in an image region where a light amount change of the predetermined light amount or more is detected. The method according to claim 1,
Wherein the controller controls the main breaker to shut off power supplied to the sub-booth from the main bus bar when it is determined that a fire has occurred inside or outside the housing part. The method according to claim 1,
Wherein the distribution board further comprises a communication module capable of data communication with a terminal of an administrator of the distribution board,
Wherein the control unit transmits a fire occurrence of the distribution panel to the terminal of the manager through the communication module when it is determined that a fire has occurred inside or outside the housing unit. The method according to claim 1,
Wherein the distribution board further comprises a memory module,
Wherein the control unit stores the internal image data and the external image data of the housing unit in real time in the memory module. 14. The method of claim 13,
Characterized in that the memory module is housed in a protective case made of a flame resistant material.

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