KR20110075598A - Gas insulated switchgear - Google Patents

Abstract

PURPOSE: A gas insulated switchgear is provided to secure operational reliability by improving a structure of a puffer cylinder for supporting a movable pipe and a check valve. CONSTITUTION: A puffer cylinder(100) has a shape of an empty pipe. A mover pipe(110) is installed along an axial direction in an inner center part of the puffer cylinder. A valve unit(200) includes a loading groove(220) formed along a circumferential direction, a main connection hole(230), and a bypass hole(240). A ring-shaped check valve(300) is used for selectively opening or closing the connection hole or the bypass hole. A supporting guide(400) is used for preventing the escape of the ring-shaped check valve.

Description

Gas Insulated Switchgear

The present invention relates to a gas insulated switchgear (GIS), and more specifically, operation reliability through structural improvement of a popper cylinder for separating a space between a compression chamber and a thermal chamber and supporting a mover pipe and a reverse displacement installed therein. A new type of gas insulated switchgear (GIS) is provided.

In general, gas insulated switchgear (GIS) is a metal sealed container (tank) that uses insulation gas (SF ₆ ) with excellent insulation performance and extinguishing function as an insulation medium to accommodate conductors and various protective devices. It is a water substation facility with improved circuit breakers, circuit breakers, disconnecting switches, and earthing switches.

As shown in FIGS. 1 and 2, a popper cylinder 10 constituting a circuit breaker among the components of the gas insulated switchgear supports a movable pipe 11 and forms a series of spaces for compressing the gas required for the extinguishing. Configuration.

As the valve bundle 20 is integrally formed on the inner circumferential surface of the popper cylinder 10, the spaces of the compression chamber 12 and the heat chamber 13 are respectively distinguished, and the valve bundle 20 has a reverse displacement. 30 is provided so that the compression chamber 12 and the thermal chamber 13 are selectively communicated with each other.

That is, when an arc is generated as the gap between the movable arc contactor 1a and the fixed arc contactor 2a is separated during the open operation of the breaker, the heat gas of the nozzle upstream of the nozzle expanded by the arc flows back into the heat chamber 13 while the heat is released. The pressure in the chamber 13 is raised.

At this point, if the pressure rise of the thermal chamber 13 is greater than the pressure rise due to the mechanical compression of the compression chamber 12, the reverse displacement 30 causes the compression chamber 12 and the heat chamber ( 13) close each communication hole (23a) drilled in the valve bundle 20 between, and in the opposite case, each communication hole (23a) is opened while the reverse valve 30 is operated in the compression chamber 12 Compressed gas is injected into the arc through the heat chamber 13 and the nozzle upstream to extinguish the arc.

However, the conventional gas insulated switchgear as described above has a problem that the arc extinguishing capacity is low because the flow of compressed gas cannot be considered.

That is, when the reverse valve 30 is opened due to the pressure difference between the heat chamber 13 and the compression chamber 12 during the tripping operation of the circuit breaker as shown in FIG. 2, the front end of the valve bundle 20 (the heat chamber side). Part) structure has a structure in which the gas exits in two directions, so when the arc is generated, the hot gas generated at the nozzle 14 flows back to the heat chamber 13 while colliding with the gas exiting from the compression chamber 12. As the vortex is generated, the mixing of the gas in the thermal chamber 13 is lowered, thereby reducing the arc extinguishing ability.

In particular, the reverse valve 30 installed in the valve assembly 20 in the popper cylinder 10 is instantaneously operated in a very short time due to the pressure difference between the compression chamber 12 and the heat chamber 13. If the pressure applied to the reverse side 30 is not constant, the reverse side 30 is inclined to flow, in which case the reverse side 30 to the guide bolt (not shown) to support it There was a problem that the restrained operation did not occur smoothly.

In addition, the guide bolt for supporting the reverse displacement has a problem that the loosening phenomenon may occur by the repeated operation of the reverse displacement.

The present invention has been made to solve the various problems of the prior art described above, the object of the present invention is to distinguish between the space of the compression chamber and the heat chamber and to support the movable pipe pipe cylinder and the reverse displacement installed thereon It is to provide a new type of gas insulated switchgear to ensure the operation reliability through structural improvement.

According to the gas insulated switchgear according to the present invention for achieving the above object is formed in the form of an empty pipe, the inner center portion of the popper cylinder in which the movable pipe is installed along the axial direction; A space in the popper cylinder is divided into a compression chamber and a heat chamber, and a through hole through which the movable pipe is formed is formed in a central portion thereof, and a seat communicating with a space in the compression chamber is formed on a wall surface of the compression chamber side among peripheral portions. A groove in which grooves are formed along the circumferential direction, and a valve bundle portion having a main communication hole and a bypass hole passing through a space in the seating groove and a space in the heat chamber on a wall surface of the heat chamber side of the peripheral portion; A ring-shaped reverse valve for selectively opening and closing the main communication hole or the bypass hole while being installed to be movable in a direction in which the seating groove is formed while seated in the seating recess of the valve bundle part; And, it is installed on the compression chamber side wall surface of the valve bundle portion, characterized in that it comprises a support guide for preventing the separation of the ring-shaped reverse displacement.

Here, the main communication hole is formed through the space on the rear side of the seating groove to communicate the space in the heat chamber and the space in the seating groove, the bypass hole penetrates through the circumferential space of the seating groove to the heat chamber It is characterized in that it is formed to communicate the space in the space within the seating groove.

In addition, the main communication hole and the bypass ball formed in the valve bundle portion is characterized in that formed in plurality along the circumferential direction of the corresponding portion.

In addition, the ring-shaped reverse displacement is formed to a thickness enough to completely close each bypass hole when moved to the compression chamber side in the seating groove and each of the bypass when moved to the heat chamber side in the seating groove The pass hole is to be opened, the main communication hole is characterized in that it is formed to a thickness enough to close completely.

In addition, the support guide is formed in a disk shape so as to obstruct the compression chamber side wall surface of the valve bundle portion, the through hole through which the movable pipe is formed in the central side portion of the support guide and at the circumferential side portion of the support guide Characterized in that a plurality of opening holes are formed in communication with the seating groove of the valve bundle portion.

As described above, the gas insulated switchgear of the present invention is configured to selectively open and close the two chambers while the ring-type reverse displacement is moved only by the pressure difference between the compression chamber and the thermal chamber. An inoperable state can be prevented, thereby resulting in an improved operation reliability.

In particular, as there is no separate structure for coupling the ring-shaped reverse displacement, such as guide bolts, there is an effect that the assembly can be made conveniently.

In addition, the gas insulated switchgear of the present invention is configured such that the low-temperature gas in the compression chamber flows into the heat chamber only through each bypass hole, and each of the bypass holes is configured to open toward the inner circumferential surface side of the popper cylinder, so that the main communication hole is Vortex generation at the formed site has an effect that can be prevented in advance.

Hereinafter, specific embodiments for the implementation of the present invention will be described with reference to FIGS. 3 to 6.

First, the gas insulated switchgear according to the preferred embodiment of the present invention as shown in Figures 3 and 4 attached largely the paper cylinder 100, the valve assembly 200, the ring-shaped reverse valve 300, the support guide It is configured to include.

This will be described in more detail below for each configuration.

First, the popper cylinder 100 is a series of configurations that form a space for compressing the gas (SF ₆ gas) required for extinguishing while supporting the mover pipe 110.

The popper cylinder 100 has an empty pipe inside, and the mover pipe 110 is installed along an axial direction at an inner central portion thereof.

In this case, the mover pipe 110 is a series of components for discharging hot gas generated during the breaking operation of the circuit breaker, and the movable arc contact 111 is coupled to the front surface.

In addition, the front surface of the popper cylinder 100, the nozzle for guiding the gas existing in the space in the popper cylinder 100 to the arc generated while the movable arc contact 111 is separated from the fixed arc contact 21 140 is installed.

Next, the valve bundle 200 is a part that divides the space inside the popper cylinder 100 into the compression chamber 120 and the thermal chamber 130.

The valve bundle 200 has a through hole 210, a seating groove 220, a main communication hole 230, and a bypass hole 240, respectively.

Here, the through hole 210 is a hole through which the mover pipe 110 penetrates, and is formed at a central side portion of the valve bundle 200.

In addition, the seating groove 220 is a groove in which the ring-shaped reverse finger 300 to be described later is seated, and is recessed along the circumferential direction on the wall surface of the compression chamber 120 side among the circumferential portions of the valve bundle 200. While being formed to communicate with the space in the compression chamber 120.

In addition, the main communication hole 230 and the bypass hole 240 is a series of configurations in which the space in the seating groove 220 and the space in the heat chamber 130 communicate with each other, It is formed in plurality along the circumferential direction on the wall surface of the heat chamber 130 side among the circumferential side parts.

In this case, each of the main communication hole 230 is formed so as to communicate the space in the heat chamber 130 and the space in the seating groove 220 through the rear side space of the seating groove 220, each bypass The ball 240 is formed to communicate the space in the heat chamber 130 and the space in the seating groove 220 through the space around the seating groove 220.

On the other hand, the valve bundle 200 as described above may be formed integrally in the popper cylinder 100, as well as manufactured separately from the popper cylinder 100 is configured to be coupled and fixed in the popper cylinder 100 You may.

Next, the ring-shaped check valve 300 is a series of configurations that selectively install the space in the compression chamber 120 and the heat chamber 130 while being installed in the valve bundle 200.

The ring-shaped reverse valve 300 is formed in a ring shape as shown in FIG. 5 and is seated in the seating groove 220 of the valve bundle 200, and the pressure in the compression chamber 120 and the heat chamber 130 is increased. Due to the difference, the seating groove 220 is installed to be movable back and forth along the direction in which the seating groove 220 is formed.

In this case, the ring-shaped reverse finger 300 is formed to a thickness enough to completely close each bypass hole 240 when moved to the compression chamber 120 in the seating groove 220 When the bypass holes 240 are opened in the seating grooves 220, the bypass holes 240 are opened, and the main communication holes 230 are formed to have a thickness that can be completely closed.

Of course, the ring-shaped reverse finger 300 is preferably formed of a material excellent in thermal deformation (for example, metal or ceramic material).

Next, the support guide 400 is a series of configurations to prevent the ring-shaped reverse displacement 300 is separated from the seating groove 220 of the valve bundle 200, the compression of the valve bundle 200 The chamber 120 is installed on the wall surface.

The support guide 400 is formed in a disk shape so as to block the wall surface of the compression chamber 120 side of the valve bundle 200. This is as shown in Figure 6 attached.

In addition, a through hole 410 through which the mover pipe 110 penetrates is formed in a central side portion of the support guide 400, and a circumferential side portion of the support guide 400 of the valve bundle 200 is provided. A plurality of opening holes 420 communicating with the seating groove 220 is formed.

At this time, each of the opening hole 420 is spaced apart along the circumferential direction of the support guide 400, so that the flow of SOHO through the seating groove 220 is possible, the departure of the ring-shaped reverse side 300 Will be prevented.

In the following, the operation by the configuration of the gas insulated switchgear according to the embodiment of the present invention configured as described above will be described.

First, when the breaker is closed (closed) state, the ring-shaped check valve 300 installed in the valve assembly 200 as shown in Figure 4 attached to the rear side (compression chamber side) of the inside of the seating groove 220 By blocking the openings 420 of the support guide 400 while forming the moved state, the spaces in the compression chamber 120 and the heat chamber 130 are kept closed.

When the blocking operation (open operation) of the circuit breaker is performed in the above-described state, the space in the compression chamber 120 is compressed by the forward movement of the mover pipe 110, and the pressure in the compression chamber 120 is increased. .

In this process, if the pressure in the compression chamber 120 is higher than the pressure in the heat chamber 130, the reverse displacement 300 is moved to the front side (heat chamber side) in the seating groove by the pressure difference. In addition to opening each opening hole 420 of the guide 400, the inner space of the seating groove 220 is in communication with each bypass hole 240. This is as shown in Figure 3 attached.

In addition, when the bypass hole 240 is in communication with the inner space of the seating groove 220 by the above-described series of processes, the low temperature SF ₆ gas existing in the compression chamber 120 is the seating groove ( 220 and the bypass holes 240 are sequentially passed through the space in the heat chamber 130.

In addition, at this time, SF ₆ gas is changed into hot gas of high temperature and high pressure by the arc generated when the fixed arc contactor 21 and the movable arc contactor 111 are separated, and flows into the thermal chamber 130 through the nozzle 140. do.

At this time, the low-temperature SF ₆ gas flowing from the compression chamber 120 flows along the inner wall portion of the popper cylinder 100 while passing through each of the bypass holes 240 and the nozzle 140. The hot gas flowing through is flowed along the outer circumferential surface portion of the mover pipe 110.

Therefore, in the thermal chamber 130, the SF ₆ gas in a relatively low temperature state introduced from the compression chamber 120 and the hot gas introduced through the nozzle 140 are mixed with each other.

In particular, each of the main communication hole 230 formed in the valve bundle 200 during the series of processes described above forms a state blocked by the ring-shaped reverse side (300).

Therefore, the hot gas that is sequentially flowed under the guidance of the outer circumferential surface portion of the movable pipe 110 does not meet the low-temperature SF ₆ gas at the site where each main communication hole 230 is formed. The problem that the vortex is generated at the formation portion of the communication hole 230 is prevented in advance so that the low temperature SF ₆ gas in the axial chamber 120 can be smoothly introduced into the thermal chamber 130.

Meanwhile, as the above-described series of processes proceed, the pressure in the thermal chamber 130 gradually increases.

In addition, when the pressure in the thermal chamber 130 is increased compared to the pressure in the compression chamber 120, the ring-shaped reverse displacement 300 is the gas introduced through each of the main communication hole 230 by the pressure difference described above. In addition to closing each opening hole 420 of the support guide 400 while being moved to the rear side (compression chamber side) of the seating groove 220 under the influence of the flow, each bypass hole 240 is also closed. do. This is as shown in Figure 4 attached.

Therefore, the gas in the thermal chamber 130 is prevented from leaking to the compression chamber 120.

In addition, as the above-described process proceeds, as the pressure in the thermal chamber 130 gradually increases, the gas in the thermal chamber 130 passes through the nozzle 140 and is injected into the arc-generated portion. The arc will be extinguished.

As a result, the arc extinguishing performance of the arc can be further improved because the gas stored in the thermal chamber 130 is used only to extinguish the arc.

1 and 2 is a schematic internal configuration diagram shown to explain the internal structure of a conventional circuit breaker for gas insulated switchgear

3 and 4 is a schematic internal configuration shown to explain the internal structure of the circuit breaker for a gas insulated switchgear according to an embodiment of the present invention.

Figure 5 is a schematic perspective view for explaining the ring-shaped reverse displacement of each configuration of the circuit breaker for gas insulated switchgear according to an embodiment of the present invention

Figure 6 is a schematic perspective view for explaining the support guide of each configuration of the circuit breaker for gas insulated switchgear according to an embodiment of the present invention

Explanation of symbols for main parts of the drawings

100.Popper Cylinder 110.Motor Pipe

111. Movable arc contact 120. Compression chamber

130. Thermal chamber 140. Nozzle

200. Valve assembly 210. Through hole

220. Settlement groove 230. Main communication hole

240. Bypass ball 300. Ring type reverse side

400. Support guide 410. Through hole

420. Aperture

Claims (5)

An inside of which is formed in a hollow pipe shape, and an inner center portion of which includes a popper cylinder in which a movable pipe is installed along an axial direction; A space in the popper cylinder is divided into a compression chamber and a heat chamber, and a through hole through which the movable pipe is formed is formed in a central portion thereof, and a seat communicating with a space in the compression chamber is formed on a wall surface of the compression chamber side among peripheral portions. A groove in which grooves are formed along the circumferential direction, and a valve bundle portion having a main communication hole and a bypass hole passing through a space in the seating groove and a space in the heat chamber on a wall surface of the heat chamber side of the peripheral portion; A ring-shaped reverse valve for selectively opening and closing the main communication hole or the bypass hole while being installed to be movable in a direction in which the seating groove is formed while seated in the seating recess of the valve bundle part; And, And a support guide installed on the compression chamber side wall of the valve bundle part to prevent the ring-shaped reverse displacement from being released. The method of claim 1, The main communication hole is formed to pass through the space on the rear side of the seating groove to communicate the space in the heat chamber and the space in the seating groove, The bypass hole is a gas insulated switchgear, characterized in that to pass through the space around the seating groove to communicate the space in the heat chamber and the space in the seating groove The method of claim 1, The main communication hole and the bypass ball formed in the valve bundle portion is a gas insulated switchgear, characterized in that formed in plurality in the circumferential direction of the corresponding portion. The method of claim 1, The ring-shaped reverse displacement When it is moved to the compression chamber side in the seating groove is formed to a thickness enough to completely close each bypass hole, and when it is moved to the heat chamber side in the seating groove, each bypass hole is to be opened, Gas communication switchgear characterized in that the main communication hole is formed to a thickness enough to close completely. The method of claim 1, The support guide is formed in a disk shape so as to block the compression chamber side wall surface of the valve bundle, Gas insulated opening and closing, characterized in that the central side of the support guide is formed with a through hole through which the mover pipe passes, and a plurality of openings are formed in the circumferential side of the support guide to communicate with the seating grooves of the valve bundle. Device.

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