KR102160052B1 - Arc Ventilation System of Distrbuting Board - Google Patents

Abstract

The present invention relates to an arc discharge system of a switchboard, and more particularly, to an arc discharge system of a switchboard that minimizes an arc flowing forward to prevent damage.
In the arc discharge system of the switchboard according to an embodiment of the present invention, in the arc discharge system of the switchboard in which a plurality of compartments are provided, a first compartment in which a power device capable of drawing in and out of the plurality of compartments is accommodated, An arc cut-off part is formed to block a space between the power device and the first compartment in the operating position.

Description

Arc Ventilation System of Distrbuting Board

The present invention relates to an arc discharge system of a switchboard, and more particularly, to an arc discharge system of a switchboard that minimizes an arc flowing forward to prevent damage.

In general, a switchboard is a device used to monitor, control, and protect the power system.The switchboard is used to accommodate various electric devices such as circuit breakers and current transformers for operation or control of power plants and substations, and motor operation.

When an arc occurs due to short circuit, ground fault, insulation breakdown, etc. inside the switchboard, high temperature and high pressure arc gas is generated inside the switchboard. The switchboard must be able to protect the power equipment and people of the switchboard by swiftly discharging the high-temperature and high-pressure arc gas generated by such an accident to the outside.

Accordingly, the switchboard is provided with a duct to configure a path through which the arc gas is discharged. The arc gas generated inside the switchboard may be discharged to the outside through a duct provided in the switchboard.

These arc discharge passages and ducts need to cool the arc gas or delay the discharge time in order to reduce ambient damage due to the high temperature gas discharged to the outside.

1 shows the structure of a switchboard according to the prior art.

In the case of a high-voltage switchboard, it is usually composed of multiple stages. The switchboard 1 according to the prior art includes a transformer room 2 provided at the lower end, a circuit breaker room 3 provided at the middle end, a low-voltage equipment room 4 provided at the upper end, and a bus bar provided at the rear end thereof. It consists of a cable room (5) and the like.

On the other hand, an arc discharge chamber 6 is provided above the circuit breaker chamber 3, that is, between the low-voltage equipment chamber 4 and the bus and cable chambers 5. In the arc discharge chamber 6, the lower surface and the side are opened so that the arc generated in the circuit breaker chamber 3 is introduced and discharged to the outside of the switchboard.

2 and 3 are side views and front views of the circuit breaker room.

A circuit breaker 7 is inserted into the circuit breaker room 3. The circuit breaker 7 includes a main circuit part (conducting part) 7a and an operation part 7b, and the operation part 7b has a protective plate 7c surrounding the four surfaces of the upper, lower, left and right sides. It protects and blocks arcs suitable for international protection marking.

When the circuit breaker 7 enters the circuit breaker chamber 3 and operates on, the circuit breaker terminal 7d is coupled to the switchboard terminal 8 (precisely, the switchboard terminal inside the terminal bushing) to form electricity.

When the circuit breaker 7 is cut off, the circuit breaker terminal 7d is separated from the switchboard terminal 8 and an arc is generated. Of course, arcs are also caused by fault currents such as short circuits, ground faults, or insulation breakdown.

Most of the arc moves to the upper arc discharge chamber 6, but some of the arc moves to the front and the arc energy is diffused toward the front door 3a.

That is, the arc gas flows out between the upper low-pressure equipment chamber 4 and the protective plate 7c, and between the side plate 9 and the protective plate 7c and diffuses forward.

In the prior art, arc energy is spread in the direction of the front door 3a as described above, and the hinge of the front door 3a and the frame is destroyed, the door handle is destroyed, or the door is filled, or arc energy is transmitted to the switchboard. There is a risk of secondary accidents, such as being released to the front, resulting in personal accidents. .

The present invention was conceived to solve the above-described problem, and an object of the present invention is to provide an arc discharge system for a switchboard so that parts of a front part of a switchboard are less damaged by arc generation.

In addition, it is to provide an arc discharge system of a switchboard to reduce the discharge of arc energy in the front direction during an arc accident.

In the arc discharge system of the switchboard according to an embodiment of the present invention, in the arc discharge system of the switchboard in which a plurality of compartments are provided, a first compartment in which a power device capable of drawing in and out of the plurality of compartments is accommodated, An arc cut-off part is formed to block a space between the power device and the first compartment in the operating position.

Here, the arc blocking unit is characterized in that the power device and the power device is partially overlapped in a direction perpendicular to the lead-in/out direction.

In addition, the arc blocking portion is characterized in that provided on the upper panel or the side panel of the first compartment.

In addition, protective plates are formed on upper, lower, left, and right sides of the power device, and the arc blocking portion partially overlaps the protective plate.

In addition, a second compartment and a third compartment disposed adjacent to each other are provided at an upper portion of the first compartment, and the upper panel may be disposed at a lower portion of the first upper panel and the third compartment disposed below the second compartment. It is composed of a second upper panel to be disposed, and a partition frame is provided at a rear portion of the first upper panel, and the protective plate is disposed below the partition frame at the driving position of the power device.

In addition, the arc blocking portion is characterized in that it comprises a first extension plate provided on the front portion of the second upper panel.

In addition, the height of the front portion is characterized in that it is formed equal to the height of the partition frame.

In addition, the lower end of the first extension plate is characterized in that it extends to a position lower than the height of the upper plate of the protective plate.

In addition, a protection plate is provided on a side panel of the first compartment, and the protection plate is supported by a support plate.

In addition, a second extension plate is bent on the protection plate or the support plate, and a part of the second extension plate partially overlaps the side plate of the protection plate.

In addition, the third compartment is characterized in that it acts as a passage through which the arc generated in the first compartment can be discharged.

According to the arc discharge system of the switchboard according to each embodiment of the present invention, arc energy flowing forward is minimized by providing an arc cutoff part overlapping with the protection plate or the protection plate of the circuit breaker on the upper panel and the side panel of the compartment through which the power device is drawn in. do.

That is, most of the arc energy is guided to the arc discharge chamber above the breaker chamber, and the arc is safely discharged to the outside.

In addition, the arc cut-off unit is also provided in a transformer room to cut off arcs generated in the transformer room or reduce arc energy according to a time delay.

1 is a perspective view of a switchboard according to the prior art.
2 and 3 are a side view and a front view of a circuit breaker room in a switchboard according to the prior art.
4 is a side view of a switchboard according to an embodiment of the present invention.
5 is a partial perspective view of FIG. 4. The first and fourth compartments are shown. Here, the breaker and transformer are removed.
6 is a side view of the first compartment.
7 is a partial perspective view in FIG. 6.
8 and 9 are perspective views of an upper panel and a side panel of the first compartment.
10 and 11 are a top plan view and a partial perspective view of the first compartment.

Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings, but this is for explaining in detail enough that a person of ordinary skill in the art can easily carry out the invention. It does not mean that the technical spirit and scope of the invention are limited.

The arc discharge system of the switchboard according to each embodiment of the present invention will be described in detail with reference to the drawings.

In the arc discharge system of the switchboard according to an embodiment of the present invention, in the arc discharge system of the switchboard in which a plurality of compartments are provided, the first compartment 13 in which power devices capable of being brought in and out of the plurality of compartments are accommodated, It is characterized in that the arc cut-off part is formed to block a space between the power device and the first compartment 13 at the operating position of the power device.

The arc discharge system of the switchboard 10 according to an embodiment of the present invention includes a first compartment 13 installed in a part of the switchboard enclosure; A second compartment (14) and a third compartment (16) provided above the first compartment (13); Including; a circuit breaker 20 which is installed in the first compartment 13 and provided with a protective plate 25 on the upper, lower, left, and right sides of the operation part 24, and includes, of the first compartment 13 The upper panel 40 and the side panel 50 are characterized in that an arc blocking portion overlapping the protective plate 25 at the operating position of the circuit breaker 20 is formed.

First, reference will be made to FIGS. 4 to 7. FIG. 4 is a side view of a switchboard according to an embodiment of the present invention, FIG. 5 is a partial perspective view of FIG. 4 in which the first and fourth compartments are shown, FIG. 6 is a side view of the first compartment, and FIG. 7 is Is a partial perspective view.

The enclosure (cabinet) 11 of the switchboard 10 will be described first. The enclosure of the switchboard 10 according to an embodiment of the present invention is divided into a plurality of compartments. For this example, the enclosure 11 of the switchboard 10 includes a first compartment (breaker room) 13, a second compartment (low pressure equipment room) 14, a third compartment (arc discharge room) 16, and a fourth compartment ( A transformer room) 12 and a fifth compartment (bus and cable room) 15 may be included.

The high-voltage switchgear is usually formed in multiple stages. Multi-stage switchgear includes compartments provided in two or more stages, respectively. In this embodiment, an enclosure of a switchboard consisting of three stages is shown. The compartment installed at the first stage (lower end) of the switchboard enclosure 11 is referred to as the fourth compartment (transformer room) 12, and the compartment installed at the second stage (middle end) is the first compartment (breaker room) 13 ). Each of the fourth compartment 12 and the first compartment 13 may contain power devices capable of being brought in or out. Such a device may be a circuit breaker 20 or a transformer 30. That is, a circuit breaker may be inserted into the first compartment 13 and a transformer may be inserted into the fourth compartment 12.

A second compartment (Low Voltage Compartment) 14 is provided above the first compartment 13. At this time, the second compartment 14 is formed to be shorter than the length of the fourth compartment 12 and the first compartment 13 (a length in the front and rear direction). In the second compartment 14, a low-voltage device, an instrument transformer, a current transformer, or an accessory device may be installed.

At the rear of the fourth compartment 12 and the first compartment 13, a fifth compartment (bus bar and cable compartment) 15 is provided.

A third compartment (arc discharge chamber) 16 is provided between the second compartment 14 and the bus and cable compartment 15.

The left and right sides and lower surfaces of the third compartment 16 are all or partially open. That is, openings are formed on the left, right side and bottom surfaces of the third compartment 16, respectively. Accordingly, the third compartment 16 becomes a passage through which the arc gas generated in the lower first compartment 13 flows not only through the lower surface opening but also to the left and right sides.

A first cover 42 (flap) is provided on the lower surface of the third compartment 16. The first cover 42 is installed to be opened by rotation. For example, one side of the first cover 42 is hinged. When the first cover 42 is opened, the upper surface of the first compartment 13 is opened. Accordingly, the first cover 42 becomes a discharge passage for the arc gas generated in the first compartment 13. When arc gas is generated in the first compartment 13, the first cover 42 is opened by the pressure of the arc gas to enter the third compartment 16, and then the arc gas is discharged from the left side of the third compartment 16. , It flows to the side through the right opening (21).

The second compartment 14 and the third compartment 16 may be provided above the first compartment 13.

The circuit breaker 20 may be installed in the fourth compartment of the first stage or the first compartment of the second stage. In the present embodiment, the circuit breaker 20 is described as an example installed in the first compartment of the second stage.

The circuit breaker 20 is a main circuit part (conducting part or cut-off part) 21, a breaker terminal 22 and 23 respectively formed on the upper and lower parts of the main circuit part 21, and an operation part installed on the front of the main circuit part 21 Includes (24).

The operation unit 24 is provided with a protective plate 25 on the upper, lower and left and right sides. The protective plate 25 is for protection and arc blocking according to the IP class. (Here, the IP grade is a standard that sets the dustproof and waterproof grade for solid and liquid.)

The protective plate 25 may be formed in a "a" shape. The upper plate 26 of the protective plate 25 may be bent rearward, and the side plate 27 of the protective plate 25 may be bent forward.

Upper panels 35 and 40 are provided on the upper surface of the first compartment 13 (lower surfaces of the second and third compartments 14 and 16). Each compartment can be composed of panels on the top, bottom, front, rear, left and right sides. Here, the panels can be shared in adjacent compartments. For example, the second upper panel 40 of the first compartment 13 may be shared as a lower panel of the third compartment 16. Also, each panel can be supported by a frame.

The upper panels 35 and 40 may include a first upper panel 35 provided on a lower surface of the second compartment 14 and a second upper panel 40 provided under the third compartment 16 .

8 is a perspective view of the second upper panel of the first compartment.

A partition frame 17 may be provided on a rear portion of the first upper panel 35. The partition frame 17 is formed to extend downward than the first upper panel 35.

The second upper panel 40 is provided with an opening 41 formed by a plurality of holes. The arc generated when the circuit breaker 20 is cut off or the arc generated by the fault current moves to the third compartment 16 above through the opening 41.

As described above, the opening part 41 is provided with a first cover 42 installed to be opened and closed by a hinge or the like. The first cover 42 is normally closed (a state in which energization occurs normally), and is opened by the pressure of the arc when an arc occurs, and the opening 41 is opened.

The front portion 43 of the second upper panel 40 may extend to a predetermined height (length). In this case, the extended height (length) may be formed equal to the height (length) of the partition frame 17 provided at the rear of the first upper panel 35. The partition frame 17 of the first upper panel 35 and the front surface 43 of the second upper panel 40 are installed adjacent to each other.

In a state in which the circuit breaker 20 is inserted into the first compartment 13 (operation position), the protective plate 25 of the circuit breaker 20 is disposed at the position where the partition frame 17 is installed (see FIG. 4). The gap between the partition frame 17 and the protective plate 25 is kept as small as possible. However, in order to avoid interference when the circuit breaker 20 moves, a gap between the protective plate 25 and the partition frame 17 inevitably exists.

In each compartment, an arc cut-off part is provided to block (shield) the spaced space between the panel constituting the compartment and the power equipment accommodated therein.

The arc blocking portion may be formed of a plate extending or bent on each panel.

In addition, the arc cut-off unit may be formed in a direction perpendicular to the in/out direction of the power device, and may be provided to partially overlap the power device.

The front part 43 is provided with a first extension plate 45 as an arc blocking part. The first extension plate 45 may be formed to protrude downward. At this time, the lower end of the first extension plate 45 extends downward so that it is disposed lower than the height of the upper plate 26 of the protection plate 25. Accordingly, the first extension plate 45 partially overlaps the protective plate 25 when viewed from the front or the rear. In addition, the first extension plate 45 completely covers the gap (separation space) between the protective plate 25 and the partition frame 17 when viewed from the front or the rear.

The first extension plate 45 is formed in a direction perpendicular to the lead-in/out direction of the power device. Accordingly, the arc flowing forward among the arcs generated by the circuit breaker 20 flows along a bypass path that is blocked by the first extension plate 45 and is switched upward or downward. Among them, the arc that is converted upward and flows into the third compartment 16 through the opening 41, and the arc flowing downward is between the first extension plate 45 and the upper plate 26 of the protective plate 25. It proceeds forward through the gap.

That is, some of the arcs generated by the circuit breaker 20 and flowing forward are turned upward and introduced into the third compartment 16, and some are turned downward and proceed forward through the bypass path. The arc proceeding forward through the bypass path has a delay time and the arc pressure decreases. Therefore, even if the forward arc reaches the first compartment door 18 provided in front of the first compartment 13, the influence of the arc pressure decreases, thereby preventing damage to the first compartment door 18 and the user. Does not.

In Figure 9 a side panel of the first compartment is shown.

A protection plate 52 and a support plate 55 may be provided inside the side panel 50 of the first compartment 13. The protection plate 52 is installed at a predetermined distance from the side panel 50 by the support plate 55.

At this time, a second extension plate 56 is provided on the protective plate 52 or the support plate 55. For example, the second extension plate 56 is bent at the rear end of the support plate 55.

The second extension plate 56 extends in the left and right directions when viewed from the front. That is, the second extension plate 56 is formed in a direction perpendicular to the side panel 50 (a direction perpendicular to the in/out direction of the power device). Accordingly, it partially overlaps with the side plate 27 of the protective plate 25 when viewed from the front or rear. That is, when viewed from the front or the rear, the gap between the side plate 27 and the side panel 50 (or the protective plate) of the protective plate 25 is completely covered. (See Figs. 10 and 11)

Accordingly, the arc flowing to the side of the arc generated in the circuit breaker 20 and flowing forward is a bypass path through the gap between the side plate 27 of the protection plate 25 and the second extension plate 56 of the support plate 55 Flows forward. That is, a time delay occurs. Thus, the arc pressure decreases.

The arc blocking unit of the above-described embodiment can also be applied to the fourth compartment 12. A protective panel 65 is provided under the upper panel 60 of the fourth compartment 12 (see FIG. 5). At one end of the protective panel 65, a third extension plate 66 protrudes downward. At this time, the lower end of the third extension plate 66 extends to a position lower than the upper surface of the front protection plate 31 of the transformer 30. Accordingly, the third extension plate 66 partially overlaps the front protection plate 31 of the transformer 30. Thus, when viewed from the front or rear, the gap between the upper panel 60 of the fourth compartment 12 and the front protective plate 31 of the transformer 30 is closed.

A second support plate 71 is provided on the side panel 70 of the fourth compartment 12. A fourth extension plate 72 is bent at an end of the second support plate 71. The fourth extension plate partially overlaps the side surface of the front protection plate 31 of the transformer 30. Thus, when viewed from the front or rear, the gap between the side panel 70 of the fourth compartment 12 and the front protective plate 31 of the transformer 30 is closed.

According to the arc discharge system of the switchboard according to each embodiment of the present invention, arc energy flowing forward is minimized by providing an arc cutoff part overlapping with the protection plate or the protection plate of the circuit breaker on the upper panel and the side panel of the compartment through which the power device is drawn in. do.

In other words, most of the arc energy is guided to the compartment where the power equipment is drawn in, particularly the arc discharge chamber above the breaker room, so that the arc is safely discharged to the outside.

In addition, the arc cut-off unit is also provided in a transformer room to cut off arcs generated in the transformer room or reduce arc energy according to a time delay.

The embodiments described above are embodiments for implementing the present invention, and those of ordinary skill in the art to which the present invention pertains will be able to make various modifications and variations without departing from the essential characteristics of the present invention. Accordingly, the embodiments disclosed in the present invention are not intended to limit the technical idea of the present invention, but to explain the technical idea, and the scope of the technical idea of the present invention is not limited by these embodiments. That is, the scope of protection of the present invention should be interpreted by the following claims, and all technical ideas within the scope equivalent thereto should be interpreted as being included in the scope of the present invention.

10 switchboard 11 enclosure
12 Compartment 4 (transformer room) 13 Compartment 1 (breaker room)
14 Compartment 2 (low voltage equipment room) 15 Compartment 5 (bus and cable room)
16 3rd compartment (arc discharge room) 17 division frame
18 front door 20 breaker
21 Left and right openings 21 Main circuit
22,23 breaker terminal 24 control panel
25 Protective plate 26 Top plate
27 shroud 30 transformer
31 Front protection plate 40 Top panel
41 opening 42 first cover
43 Front 45 First extension plate
50 side panel 52 shroud
55 Support plate 56 Second extension plate
60 Top panel 65 Protection panel
66 Third extension plate 70 Side panel
71 2nd support plate 72 4th extension plate

Claims (11)

In the arc discharge system of the switchboard in which a plurality of compartments are provided,
In the first compartment in which the power equipment capable of drawing in and out of the plurality of compartments is accommodated,
An arc blocking portion is formed to block a space between the power device and the first compartment at the operating position of the power device,
The arc blocking portion is provided on the upper panel of the first compartment,
The arc blocking portion includes a first extension plate provided on the front portion of the upper panel,
Protective plates are formed on the upper, lower, and left and right sides of the power device,
The arc discharge system of a switchboard, wherein the first extension plate partially overlaps the protective plate. The method of claim 1,
The arc discharge system of a switchboard, wherein the arc cut-off part partially overlaps in a direction perpendicular to a lead-in/out direction of the power device and the power device. The arc discharge system according to claim 2, wherein the arc cut-off part is further provided on a side panel of the first compartment. delete The method of claim 1, wherein a second compartment and a third compartment disposed adjacent to each other are provided above the first compartment,
The upper panel is composed of a first upper panel disposed under the second compartment and a second upper panel disposed under the third compartment,
A partition frame is provided on the rear portion of the first upper panel,
The arc discharge system of a switchboard, wherein the protective plate is disposed under the partition frame at the operating position of the power device. delete The arc discharge system according to claim 5, wherein the height of the front part is formed equal to the height of the partition frame. The arc discharge system of a switchboard according to claim 1, wherein the lower end of the first extension plate extends to a position lower than the height of the upper plate of the protection plate. The arc discharge system of a switchboard according to claim 3, wherein a protection plate is provided on a side panel of the first compartment, and the protection plate is supported by a support plate. The arc discharge system according to claim 9, wherein a second extension plate is bent on the protection plate or the support plate, and a part of the second extension plate partially overlaps the side plate of the protection plate. The arc discharge system of a switchboard according to claim 5, wherein the third compartment serves as a passage through which the arc generated in the first compartment can be discharged.

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