KR20150122391A - Inspection method of the inner part of the cable room of switch board using thermal infrared camera and energy-reflecting thermodynamic reflector and switch board using the same - Google Patents

Abstract

The present invention relates to a switchboard structure including an energy-reflecting thermodynamic reflector to easily inspect the inside by using a thermal infrared camera and a method for inspecting the inside of a switchboard cable room using the same and, more specifically, is to provide a switchboard structure of a switchboard in which it is difficult to inspect the state of a dead angle area in a cable room, which is contrived to inspect the state in the cable room through an image reflected on a thermal infrared camera through an energy-reflecting thermodynamic reflector by providing the energy-reflecting thermodynamic reflector on the bottom of the cable room, and a method for inspecting the inside of the switchboard cable room. According to the present invention, a connection portion between devices in a mother ship room is inspected by opening a room pressure valve provided on a ceiling face of a switchboard and photographing the mother ship room by a thermal infrared camera, an inner state of a lower cable room is inspected by opening a front door of the cable room and photographing the inside by a thermal image camera, an energy-reflecting thermodynamic reflector is provided on the bottom of the cable room, it is possible to easily and accurately inspect the inner state by using a thermal image reflected by the energy-reflecting thermodynamic reflector. In addition, by using the energy-reflecting thermodynamic reflector having a variable structure, it is possible to confirm temperature distribution based on partial heating in a connection portion or the like in a dead angle area by adjusting the angle of the energy-reflecting thermodynamic reflector, and it is possible to prevent an accident by repairing the switchboard before an error occurs.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method of inspecting an interior of a cable cabin using a thermo-infrared camera and an energy reflection thermodynamic reflector, the same}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a structure of an electrical switchboard having an energy reflection type thermodynamic reflector for easy internal inspection using a thermal infrared camera, A thermo-dynamic reflector is provided on the bottom surface of the cable room in a switchboard, for example, a back wall type switchboard and a double-sided symmetrical switchboard, so that the thermal image reflected in the thermal infrared camera through the energy- And a method of inspecting an interior of a cabinet of an electric cabin using the same.

Generally, water basins, switchboards, and distribution boards receive high-voltage or extra-high voltage electricity supplied by electric power companies, convert them to the voltages used in the customers, and distribute them to the load facilities.

Such a number, a ship, a distribution board, an MCC, etc. (hereinafter, simply referred to as an "switchboard") is a cubicle of a partition structure when viewed from the outside, and includes power devices such as a high voltage circuit breaker and a current transformer, Electric parts are provided. In addition, a bus bar for connecting the power devices to each other according to the power system and wiring for measuring and monitoring the power devices are disposed in the inside of the switchboard, and the lower part of the cubicle- And a hole for wiring the monitoring wiring and the wiring of the load equipment is formed on the bottom surface of the switchboard. Further, the back surface is made of an iron plate, and doors for inspecting the inside are generally provided on the front and rear portions.

On the other hand, the conventional switchboard has a problem that the cable is too long and the cable thread and the relay are not completely separated, so that interferences are generated between the internal equipments and safety can not be ensured. This phenomenon occurs more severely when a switchboard is constructed with a two-layer laminated structure for spatial efficiency.

In order to solve this problem, Korean Patent No. 10-1336734 minimizes the length of cable by constructing a low-pressure chamber, a cut-off chamber and a cable chamber sequentially on the front surface of the power distribution panel in the construction of the switchboard, And a wall-mounted type switchboard that can be completely separated and secured in stability.

However, since such a wall-mounted type switchboard is attached to the wall, it is only possible to inspect through the front door for internal inspection. The above patent has an advantage that it is easy to check each equipment by providing a low pressure chamber, a cutoff chamber, and a cable chamber vertically up and down, but it is not easy to check the condition of the rear surface of each equipment. Particularly, when the rear surface of the switchboard is closed, it is difficult to check through the rear door, so there is a problem in that there is no way to confirm abnormal overheating or the like at the connection part of the internal equipment.

If abnormal overheating occurs at the connection part inside the switchgear, gas or steam of high temperature and high pressure will be generated, and the switchboard will be destroyed or the equipment or circuit therein will be damaged. Therefore, it is necessary to appropriately remove such high-temperature high-pressure gas or vapor, in other words, an arc. The discharge hole or the pressure plate (discharge pressure side) is installed and removed from the ceiling surface of the switchboard.

In particular, in the case of an ASSEMBLY with a closed rear panel, it is often the case that the connection portion of each device is present in a rectangular area, so that it is difficult to check the inside of the ASSEMBLY There was a need for measures to solve this problem.

≪ Related Prior Art Literature >

Korean Patent No. 10-1336734

Korean Patent No. 10-0583791

Korean Registered Utility Model No. 20-0398674

Korean Patent No. 10-0230530

Korean Patent No. 10-0257924

Korean Patent No. 10-0205675

The present invention has been developed in order to overcome the problems and limitations of the prior art as described above, and it is an object of the present invention to provide a rear cabinet, And a double-sided symmetrical type switchboard, it is possible to anticipate the occurrence of an arc by checking the state of the connection part between the cable-compartment internal devices in advance, thereby providing a switchboard structure capable of preventing damage to the switchboard, We do thing as problem.

According to an aspect of the present invention,

In the case of an electric distribution panel in which it is difficult to check the state of a rectangular area in a cable chamber, an energy reflection type thermodynamic reflector is provided on a bottom surface of a cable room located at the bottom, Provides a switchgear structure designed to check the condition of the rectangular area inside the cable compartment.

In a preferred embodiment of the present invention, the switchboard is a rear-wall type switchboard or a both-sided symmetrical switchboard.

In the preferred embodiment of the present invention, the back wall type switchboard is characterized in that the low-pressure chamber, the cut-off chamber and the cable room are sequentially positioned under the upper surface of the front portion of the power distribution board and the bus barrel is disposed above the rear portion of the power distribution board, A cable bulkhead is disposed between the cable chamber and the bus barrel disposed on the rear portion of the switchboard, and the upper ceiling surface of the bus barrel is provided with an arc- And an energy reflection type thermodynamic reflector is provided on the bottom surface of the rear portion of the cable room so as to check the state of a connection portion located in a rectangular area within the cable room using a thermal infrared camera.

Further, in a preferred embodiment of the present invention, a state of the inside of the bus barrel is inspected by using a thermal infrared camera by opening the pressure relief provided on the front surface of the upper part of the bus bar of the rear wall part type switchboard.

Further, in a preferred embodiment of the present invention, the front door of the cable room of the rear wall part type switchboard is opened and the state of the connection part in the rectangular area inside the cable room is checked from the thermal image obtained through the energy reflection type thermodynamic reflector using the thermal infrared camera .

Also, in a preferred embodiment of the present invention, the energy reflective thermodynamic reflector provided on the bottom surface of the rear portion of the cable thread of the rear wall type switchboard is fixed or rotatable.

Further, in a preferred embodiment of the present invention, the double-sided symmetrical switchboard is characterized in that the low-pressure chamber, the cut-off chamber and the cable chamber are sequentially symmetrically arranged in the front and rear portions of the switchboard, A vertical partition wall is provided between the front cable room and the rear cable room and a vertical partition wall for isolating the cable room and the integrated bus room from the vertical partition wall is provided, The front side cable room and the back side cable room are provided with a thermal infrared camera on the bottom surface of the front and rear cable rooms to check the state of the connection parts located in the rectangular areas in the front and rear cable rooms And an energy reflection type thermodynamic reflector which can be used as a reflection type reflector.

In addition, in a preferred embodiment of the present invention, the double-sided symmetrical type switchboard is configured to open the discharge port provided on the upper ceiling surface of the integrated bus barrel and check the inside of the bus bar using a thermal infrared camera.

In addition, in a preferred embodiment of the present invention, the double-sided symmetrical switchboard opens the door of the front cable and rear cable rooms, extracts heat from the thermal image obtained by reflection of the energy-reflective thermodynamic reflector using a thermal infrared camera, And to check the state of the connecting portion in the rectangular area inside the rear portion cable chamber.

Also, in a preferred embodiment of the present invention, the energy reflective thermodynamic reflector provided on the bottom surface of the front cable room and the rear cable room of the double-sided symmetrical switchboard is fixed or rotatable.

According to another aspect of the present invention, there is provided a method for inspecting an interior of a cabin of an electric cabin using an electric cabinet according to the present invention, An energy reflection type thermodynamic reflector is provided on the bottom surface of the cable compartment and the inside of the cable compartment is opened with the front door of the cable compartment opened. By photographing the inside of the cable compartment through a thermal infrared camera, And the state of the rectangular area inside the cable compartment is checked.

The features and advantages of the present invention will be described in the following. FIG. 1 is a perspective view of a cabin of a cabinet in which an energy reflection type thermodynamic reflector is installed in a cabin for easy internal inspection using a thermal infrared camera according to the present invention.

1. First, according to the structure of the switchgear according to the present invention, inspection of the inter-device connection portion of the bus barrel is performed by opening the breaker provided on the ceiling of the switchboard, photographing the bus bar with a thermal infrared camera, Can be checked.

2. In the structure of the switchgear according to the present invention, because there is a horizontal partition between the bus bar and the cable room, it is impossible to inspect the inside of the cable room in the state where the above-mentioned inflation bar is opened. Therefore, the internal condition of the lower cable room is opened by opening the front door of the cable room and checking the inside with a thermal imaging camera. It is impossible to accurately check by the thermal image due to the rectangular area that the thermal imaging camera can not capture. In the invention, an energy reflection type thermodynamic reflector is provided on the bottom surface of a cable room and an energy reflection type thermodynamic reflector is provided, and the internal state of the energy reflection type thermodynamic reflector can be accurately checked using a thermal image.

3. In addition, it is not possible to monitor the heat generation in the case of live panels in the case of existing switchboards, especially switchboards with two or more levels. The reason for this is that the inside is completely enclosed. In the case of a completely closed structure, it is possible to perform an indirect inspection using the oil temperature gauge. However, the temperature distribution due to local heating such as the connection portion can not be read. In the present invention, by using an energy reflective thermodynamic reflector having a variable structure, it is possible to confirm the temperature distribution by local heating at the connection portion of the rectangular region by slightly adjusting the angle of the energy reflective thermodynamic reflector, You can prevent accidents by repairing them before they occur.

4. The structure of the switchboard according to the present invention utilizes the characteristic that a thermal image reflected by an energy reflection type thermodynamic reflector is expressed in a similar manner to a thermal image of the real one. In particular, the rear panel closed type switchboard and the both sides symmetrical type switchboard However, it can be widely applied to various kinds of distribution boards such as extra high voltage, high voltage, low voltage, MCC, water supply, switchboard, and distribution board.

FIG. 1A is a schematic diagram showing a thermal image obtained by using a thermal infrared camera and photographing a hot spot when a hot spot is present and a thermal image reflected by a mirror (energy reflective thermodynamic reflector) Reflector) of the photographed image (right).
FIG. 1B is a schematic view showing a mirror (energy reflection type thermodynamic reflector) using a camera (left) and a photograph (left) photographing a thermal image reflected by a mirror (energy reflection type thermodynamic reflector) (Right), which is a photographed still image.
2 is a side view showing a structure of a rear wall type power distribution board according to an embodiment of the present invention.
3 is a side view showing the structure of a double-sided symmetrical switchboard according to another embodiment of the present invention.
Fig. 4 is a view showing an energy reflective thermodynamic reflector constructed in a variable rotatable type in the embodiment of the present invention. Fig.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. It should be understood, however, that the detailed description and specific examples, while indicating preferred embodiments of the invention, are given by way of illustration only, and thus are not limitative of the scope of the invention.

FIG. 1A is a schematic diagram showing a thermal image obtained by using a thermal infrared camera and photographing a hot spot when a hot spot is present and a thermal image reflected by a mirror (energy reflective thermodynamic reflector) 1B is a photograph (left) in which a thermal image reflected on a mirror (energy reflection type thermodynamic reflector) in the case where a hot spot is not present is taken using a thermal infrared camera This is a photographic image (right) of a mirror (energy reflective thermodynamic reflector) photographed using an ordinary camera.

Referring to FIG. 1A, when a hot spot is observed using a thermal infrared camera, the hot spot is reflected on a mirror (energy reflective thermodynamic reflector) to transmit radiant heat, and the radiant heat reflects the temperature of the actual hot spot almost equally (Left) from which a thermal image is photographed.

Thermal analysis data of each region (points indicated by 1, 2, and 3 in the left photograph) in this experiment are shown in Table 1 below.

Point One 2 3 Maximum temperature (℃) 28.6 30.0 43.8 Average temperature (℃) 27.7 29.2 35.0 Minimum temperature (℃) 26.9 28.3 29.8

In addition, referring to FIG. 1B, when a case where no hot spot is observed using a thermal infrared camera, the surface temperature of an actual mirror (energy reflective type thermodynamic reflector) appears when a mirror (energy reflective type thermodynamic reflector) (Left) from which a thermal image is captured.

Thermal analysis data of each region (points indicated by 1 and 2 in the left photograph) in this experiment are shown in Table 2 below.

Point One 2 Maximum temperature (℃) 28.4 22.4 Average temperature (℃) 27.5 22.0 Minimum temperature (℃) 26.4 21.7

The present invention utilizes the fact that the thermal image radiated through the mirror reflects the temperature of the actual hot spot in this way, so that the internal state, such as whether the junction located in the camera square area in the cabin of the switchgear cabin is overheated, And can be confirmed as an image result.

That is, according to the present invention, an energy reflection type thermodynamic reflector is provided on a bottom surface of a cable room located at a lower portion of the distribution panel in which the state of a rectangular area in a cable room is difficult to be checked, and is reflected by the energy reflection type thermodynamic reflector by a thermal infrared camera And the state of the rectangular area inside the cable compartment can be checked through the obtained thermal image.

The present invention can be applied to various types of switchboards as an invention for checking the state of device connection parts in an inner rectangular area in various switchboards such as extra high voltage, high voltage, low voltage, motor control panel (MCC) For example, it is suitable to be applied to a back wall type switchboard having a rear surface attached to a wall and a two-sided symmetrical switchboard having two surfaces symmetrically formed on both sides with a center at a boundary.

2 is a side view showing a structure of a rear wall type power distribution board according to an embodiment of the present invention.

2, the rear wall type switchboard to which the present invention is applied is characterized in that the low pressure chamber R1, the cutoff chamber R2 and the cable chamber R3 are sequentially located in the upper portion of the front portion of the power distribution board, A cable chamber R3 and a bus barrel R4 disposed on the rear side of the switchboard and a bus barrel R4 disposed on the rear side of the switchboard R4 are disposed on the rear side of the cabin, A horizontal partition wall 10 is provided between the upper shell 11 and the upper shell 11. The upper shell face 11 of the bus barrel R4 is provided with at least one pressure relief valve 12 for discharging an arc generated therein. And an energy reflective thermodynamic reflector (not shown) capable of checking the state of a connection portion located in a rectangular area within the cable chamber R3 by using a thermal infrared camera 14 is provided on the bottom surface 13 of the rear surface portion of the cable chamber R3 15 are provided.

Further, the rear wall part type switchboard to which the switchboard structure according to the present invention is applied includes a relay, a breaker, a bus bar, and a current transformer. The relay is installed in the low-pressure chamber R1, and the circuit breaker is installed in the lower interrupter chamber R2 of the relay. Further, on the lower side of the switchboard, a cable chamber R3 is arranged from the front portion to the rear portion to form a lower space, and a current transformer 17 is installed in this space. The current transformer 17 may be disposed under the circuit breaker in the cable chamber R3 or may be disposed on one side wall of the cable compartment R3 or below the horizontal partition wall 10 or in an electric cabinet case, It is preferable that the bus bar 19 connected to the terminal 18 penetrates the current transformer 17.

In addition, the rear wall type switchboard to which the switchboard structure according to the present invention is applied is characterized in that a discharge pressure for discharging an arc generated in the upper ceiling face 11 of the bus barrel R4 is at least The state of the inside of the bus chamber R4 can be checked by photographing a thermal image using the infrared infrared camera 14. [

Thermal imaging using the decompression valve 12 is limited to the inside of the bus barrel R4 because the horizontal barriers 10 are present between the bus barrel R4 and the cable room R3, Is difficult to check.

The present invention opens the cable compartment front door 20 to inspect the internal state of the cable compartment for inspecting the inside of the cable compartment R3 such that the connection part existing in a rectangular area such as the breaker terminal 18 is connected to the infrared camera 14), it is difficult to obtain accurate data.

Therefore, in order to solve such a problem, the energy reflection type thermodynamic reflector 15 is disposed on the bottom surface 13 of the cable compartment and the radiation heat reflected therefrom is measured to check the state of the connection part located in the rectangular area inside the cable compartment It will be possible to do.

In the rear panel type switchboard according to the present invention, the energy reflective thermodynamic reflector 15 provided on the bottom surface of the rear surface of the cable cable may be fixedly mounted, 21, and a hinge 22. (See FIG. 4) As described above, an energy reflective type thermal role reflector is provided in a rotatable type, that is, a variable structure, and the angle is slightly It is possible to check the state of the connection part in the rectangular area without restriction by adjusting it.

3 is a side view showing the structure of a double-sided symmetrical switchboard according to another embodiment of the present invention.

3, the double-sided symmetrical switchboard to which the switchboard structure according to the present invention is applied includes low pressure chambers R5-1 and R5-2, interrupter chambers R6-1 and R6-2, and cable ropes R7-1 And R7-2 are sequentially symmetrically arranged on the front and rear sides of the switchboard, an integrated bus bar R8 is located at the upper center of the switchboard, and the front cable rack R7-1 and the rear cable A vertical partition 30 is provided between the chambers R7-2 and R7-2 and a horizontal partition wall for isolating the cable chambers R7-1 and R7-2 and the integrated bus chamber R8 from above the vertical partition 30. [ 31 and the upper ceiling surface 32 of the integrated bus barrel R8 is provided with a discharge port 33 for discharging an arc generated therein, A thermal infrared camera 35 is mounted on the bottom surface 34 of the rear portion cable chamber R7-2 so as to be located in a rectangular area within the front portion cable room R7-1 and the rear portion cable room R7-2 Reflection type thermodynamic reflectors 36-1 and 36-2 capable of checking the state of a connecting portion positioned between the two reflectors.

In addition, the double-sided symmetrical type switchboard to which the switchboard structure according to the present invention is applied includes symmetrically a relay, a breaker and a current transformer on both front and rear sides. The relay is installed in the low-pressure chambers R5-1 and R5-2, and the breaker is installed in the lower part of the relay. In addition, cable rooms R7-1 and R7-2 are disposed on the front and rear sides of the switchboard, and a vertical partition 30 is provided therebetween to separate the front and rear cable rooms. The front and rear cable rooms are provided with a current transformer 37-1 and 37-2. The current transformer may be provided in the cable room under the circuit breaker, or on the side wall of the cable compartment, the horizontal partition wall, It is preferable that the bus bars 39-1 and 39-2 connected to the breaker terminals 38-1 and 38-2 pass through a current transformer.

In addition, the double-sided symmetrical type switchboard to which the switchboard structure according to the present invention is applied is characterized in that the discharge ceiling 33 for discharging an arc generated in the upper ceiling front surface 32 of the integrated bus barrel R8 is at least The state of the inside of the integrated bus barrel R8 can be checked by taking a thermal image by using the thermal infrared camera 35. In this case,

The thermal imaging using the decompression valve 33 is limited to the inside of the integrated bus barrel R8. This is because the integrated bus bar R8 and the cable compartments R7-1 and R7-2, This is because there is a horizontal partition 31 between the lower cable and the lower cable.

The present invention opens the cable compartments (front and rear) doors 40-1 and 40-2 for inspecting the inside of the cable compartments (front portion and rear portion) 37-1 and 37-2, It is difficult to obtain accurate data in the measurement using the thermal imaging camera 35. In this case, Therefore, in order to solve such a problem, the energy reflective thermodynamic reflectors 36-1 and 36-2 are disposed on the bottom surface 34 of the front cable rack R7-1 and the rear cable rack R7-2 It is possible to check the state of the connection part located in the rectangular area inside the front cable rack R7-1 and the rear cable rack R7-2.

The energy reflective thermodynamic reflector 36 provided on the bottom surface 34 of the front cable rack R7-1 and the rear cable rack R7-2 in the double-sided symmetrical switchboard to which the present invention is applied, -1, and 36-2 may be provided in a fixed shape, but it is more preferable to be provided with a rotation type using the pillars 21 and the hinge 22 so as to be able to photograph at various angles (see FIG. 4). It is possible to check the state of the connection part in the rectangular area by limiting the angle slightly by providing the energy reflecting type thermal role reflector in a rotatable type, that is, a variable structure.

The rear wall type switchboard and the two-sided symmetrical type switchboard according to the embodiment of the present invention are metal clad switchgear (MCSG) structures having relays, breakers, bus bars, cable seals and horizontal / vertical partitions, It is easy to check the device-to-device connection in the rectangular area.

The present invention also provides a method for inspecting the interior of a cable cabin using the switchboard having the structure according to the present invention. That is, according to the present invention, there is provided a method for inspecting an interior of a cabinet of an electric cabinet, comprising the steps of: providing an energy reflective thermodynamic reflector on a bottom surface of a lower cabinet, And the state of the rectangular area inside the cable compartment is inspected through a thermal image obtained by reflecting the light onto the energy reflection type thermodynamic reflector by a thermal infrared camera by photographing the inside with a thermal infrared camera in an opened state.

The method of inspecting the interior of the cabinet according to the present invention is the same as that described above with reference to the description of the structure of the power distribution board according to the present invention.

According to the switchboard structure of the present invention as described above, the inter-device connection of the bus barrel is inspected by opening the breaker provided on the ceiling surface of the switchboard and photographing the bus bar with a thermal infrared camera, Opening the front door of the cable compartment and inspecting the interior with a thermal camera, the energy reflection type thermodynamic reflector is placed on the bottom of the cable compartment and the internal state check is easy and accurate using the thermal image reflected on the energy reflective thermodynamic reflector It is possible to check. Also, the structure of the switchboard according to the present invention can be widely used in special switchboards such as special high voltage, high voltage, low voltage, motor control panel (MCC), water supply, distribution board, and distribution board.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the present invention as defined by the appended claims. You will understand.

R1: Low pressure chamber R2: Shutoff chamber
R3: Cable room R4: Bus room
R5-1, R5-2: Low-pressure chamber R6-1, R6-2:
R7-1: Front side cable thread R7-2: Rear side cable thread
R8: Integrated mothership room
10: Horizontal bulkhead 11: Moth yarn cloth front
12: Negative pressure 13: Cable room bottom
14: Thermal infrared camera 15: Energy reflective thermodynamic reflector
16: bus 17: current transformer
18: Breaker terminal 19: Bus line
20: Cable room front door 21: holding
22: Hinge
30: Vertical partition 31: Horizontal partition
32: mother ship thread front face 33:
34: Cable compartment floor 35: Thermal infrared camera
36-1, 36-2: Energy reflective thermodynamic reflector
37-1, 37-2: Current transformers 38-1, 38-2: Circuit breaker terminals
39-1, 39-2: Bus lines 40-1, 40-2: Cable thread doors

Claims (11)

In the case of an electric distribution panel in which it is difficult to check the state of a rectangular area in a cable chamber, an energy reflection type thermodynamic reflector is provided on a bottom surface of a cable room located at the bottom, A switchboard structure designed to check the condition of the rectangular area inside the cable compartment.
The switchgear structure according to claim 1, wherein the switchboard is a rear-wall type switchboard or a both-sided symmetrical switchboard.
[5] The rear wall type switchboard according to claim 2, wherein the low pressure chamber, the cutoff chamber, and the cable chamber are sequentially positioned under the upper surface of the front portion of the power distribution board and the bus barrel is disposed above the rear portion of the power distribution board, A horizontal partition wall is provided between the cable room and the bus barrel disposed on the rear portion of the switchboard, and the front upper surface of the bus barrel is provided with a pressure- And an energy reflecting type thermodynamic reflector capable of checking a state of a connection portion located in a rectangular area within the cable room by using a thermal infrared camera is provided on a bottom surface of a rear portion of the cable room.
4. The switchgear structure according to claim 3, wherein a state of the inside of the bus barrel is inspected by using a thermal infrared camera to open the discharge port provided on the upper surface of the bus barrel of the rear wall panel.
The cabinet of claim 3, wherein the front door of the cable room of the rear wall type switchboard is opened to check the state of the connecting portion in the rectangular area inside the cable compartment from the thermal image obtained through the energy reflection type thermodynamic reflector using a thermal infrared camera rescue.
[4] The switchgear as set forth in claim 3, wherein the energy reflective thermodynamic reflector provided on the bottom surface of the rear portion of the cable room of the rear wall type switchboard is fixed or rotatable.
2. The double-sided symmetrical type switchboard according to claim 2, wherein the low pressure chamber, the cutoff chamber, and the cable chamber are symmetrically disposed in order symmetrically with respect to the front portion and the rear portion of the power distribution board, A vertical partition wall is provided between the cable room and the rear cable room and a horizontal partition wall isolating the cable room and the integrated bus room from the vertical partition wall is provided. And an infrared ray camera is provided on the bottom surface of the front cable and rear cable rooms so as to check the state of the connection parts located in the rectangular area in the front cable and rear cable rooms. Type thermo-optic reflector.
The switchgear structure according to claim 7, wherein the state of the inside of the bus barrel is inspected by using a thermal infrared camera to open the discharge port provided on the upper ceiling surface of the integrated bus barrel.
[Claim 8] The method of claim 7, further comprising the steps of: opening a door of the front cable and rear cable seals to detect a state of connection between the front cable and the rear of the cable room from a thermal image obtained by reflecting the light onto an energy reflective thermodynamic reflector using a thermal infrared camera And to inspect the distribution board.
[7] The switchgear as set forth in claim 7, wherein the energy reflective thermodynamic reflectors provided on the bottom surface of the front cable and rear cable rooms are fixed or rotatable.
In the case of the switchboard which is difficult to check the condition of the rectangular area inside the cable compartment, the energy reflection type thermodynamic reflector is provided on the bottom of the cable compartment located at the lower part, and the inside of the cable compartment is opened. Wherein the state of the rectangular area inside the cable compartment is checked through a thermal image obtained by being reflected by the energy reflection type thermodynamic reflector by an infrared camera.

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