KR20180076235A - Hybrid-extinction type gas circuit breaker for gas-insulated switch gear - Google Patents

Abstract

The present invention relates to a composite extinction gas circuit breaker for a gas insulated switchgear which not only forms an eddy flow preventing unit provided in a connecting unit to be bent, but also enables the eddy flow preventing unit to be positioned on an edge side generating an eddy flow, thereby preventing the eddy flow from being generated when an expansion gas circulates. Therefore, the mixing efficiency of a heat gas and a cold gas is improved.

Description

HYBRID-EXTINCTION TYPE GAS CIRCUIT BREAKER FOR GAS-INSULATED SWITCH GEAR FOR GAS-

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a gas-insulated switchgear for a gas-insulated switchgear, and more particularly to a gas-insulated switchgear for preventing the occurrence of eddy currents in an expansion chamber, The present invention relates to a combined-articulated gas circuit breaker.

Generally, the gas insulated switchgear consists of a gas circuit breaker, a current transformer, a line disconnector / earthing switch, a bus disconnector / earthing switch, and a gas circuit breaker installed on the transmission line. It performs opening and closing operation and protects the line and load equipment by blocking the fault current when an abnormality occurs in the transmission line.

The gas circuit breaker uses gas for arc extinguishing and extinguishes the arc generated between the two contacts through gas.

Such a gas circuit breaker is classified into a Puffer type, a rotary arc type, a thermal expansion type, and a hybrid extinction type according to the arc extinguishing method, SF ₆ gas is used as a SOHO gas in a conventional gas circuit breaker.

In this case, when the circuit breaker performs the shutdown of the fault current, the arc is extinguished while blowing the compressed gas in the gap by compressing the soot gas in the compression chamber in the blocking portion by using the external driving force, Is a method of accumulating the heat of the arc generated in the breakdown of the fault current in the expansion chamber and blowing the pressure raised by the accumulated heat to the gap, and a combination of these two methods is a composite SOHO system.

In the case of the large-current shutdown, the arc heat is applied to the expansion chamber by flowing the heat gas heated by the arc to the expansion chamber, and when the current is zero, the thermal gas is injected from the expansion chamber into the inter- .

FIG. 1 is a conceptual view of a conventional gas-insulated switchgear for a gas-insulated switchgear. FIG. 2 shows a process of introducing a gas into a gas- And FIG. 3 is a conceptual diagram showing a process in which the thermal gas is mixed with the cold gas in the expansion chamber and then discharged in the conventional gas recloser for a gas insulated switchgear.

Fig. 4 is a block diagram showing a conventional gas-insulated switchgear for gas-insulated switchgear. Fig. 5 shows the process of circulating the inflation gas in the expansion chamber of the conventional gas- And FIG. 6 is a block diagram showing a circulation process of the inflating gas in a state where the vortex prevention member is installed in the expansion chamber of the conventional composite-type gas circuit breaker for a gas insulated switchgear.

7 is a detailed view showing a process of circulating the inflation gas in a state where the vortex prevention member is not installed in the expansion chamber of the conventional gas-insulated switchgear for a gas insulated switchgear. Fig. There is shown a detailed view showing a process of circulating inflation gas in a state where an anti-vortex member is installed in an inflating chamber of a combined-articulated gas circuit breaker for an insulated switchgear.

  1 to 8, the gas circuit breaker 10 of the gas insulated switchgear is provided with a movable contact 19 and a stationary contact 15. The movable contact 19 and the stationary contact 15 are separated from each other, an arc is generated and the main nozzle 13 and the auxiliary nozzle 15 are sputtered. At the same time, the high pressure in the vicinity of the nozzles 13, 15 causes the heat gas to flow into the expansion chamber 11, (D1), the introduced hot gas is mixed with the cold gas and then discharged again while circulating (D2, D3).

The interior of the expansion chamber 11 of the conventional composite SOFC 20 is configured to be a rectangular parallelepiped. The inside of the expansion chamber 11 is provided with a check valve 21, which is circular and flat.

The check valve 21 is provided on the lower side wall of the expansion chamber 11 and is provided so as to be capable of reciprocation in the expansion chamber 11.

When the movable side contact 19 and the fixed side contact 17 are separated and the nozzle neck is sprung by the arc, the movable side contact 19 and the fixed side side contact 17 are separated from the expansion chamber 0.0 > 100) < / RTI >

At this time, the check valve 21 is pushed backward by the force of the inflating gas and blocks the compressed gas passage.

The expansion chamber 11 has a closed structure except for the passage through the nozzles 13 and 15 so that the expansion gas 11 is mixed with the cold gas in the expansion chamber 11 and circulated.

When the pressure of the expansion chamber 11 is increased and the pressure of the expansion chamber 11 closer to the expansion gas inflow passage 20 becomes lower than the pressure of the expansion chamber 11, And the arc is extinguished.

The gas circuit breaker 10 of the hybrid arc extinguishing system must sufficiently flow the thermal gas into the expansion chamber 11 to obtain a flow capable of rapidly cooling the arc generated between the contacts 17 and 19 during the shutdown operation, In addition, mixing with the cold gas of the expansion chamber 11 should be performed well.

Further, when the arc pressure becomes low while the cutoff current becomes "0 ", the thermal gas in the expansion chamber 11 must be injected through the nozzles 13 and 15 without a maximum momentum loss.

However, the gas circuit breaker 10 of the conventional gas insulated switchgear has a problem that the vortex W is generated in the vicinity of the edge of the expansion chamber 11 and the cooling gas and the thermal gas are not mixed at the circulation D 3, There is a problem that the cold gas and the hot gas can not be sufficiently mixed due to the existence of the dead volume.

In order to solve the above problems, a vortex prevention member 23 having a curved portion is provided in the expansion chamber 11 and vortexes (not shown) are formed in the vicinity of the edge of the expansion chamber 11 during the circulation of the heat gas W is prevented from being generated, thereby improving the mixing efficiency of the cooling gas and the thermal gas in the expansion chamber 11. [

However, even when the vortex prevention member 23 having the curved portion is installed inside the expansion chamber 11, there is a space in which the thermal gas is circulated (D6) and the vortex W is generated and the hot gas and the cold gas are not mixed There is a problem that the mixing efficiency is significantly lowered.

SUMMARY OF THE INVENTION The present invention has been made in order to solve the above-mentioned problems, and it is an object of the present invention to provide a gas-insulated switchgear for a gas insulated switchgear which not only prevents the occurrence of vortexes in the expansion chamber, The present invention has been made in view of the above problems.

The above-described object of the present invention can be achieved by a gas-insulated switchgear comprising an expansion chamber in which inflation gas is introduced and circulated through an inflation gas inflow passage, and a vortex prevention member provided inside the inflation chamber to prevent the generation of vortex In the gas-operated type gas circuit breaker, the vortex prevention member includes: a connection portion connected to the expansion chamber; A movement path providing portion formed at the connection portion to the expansion chamber side to provide a movement path through which the inflation gas flows into the expansion chamber; And at least one discharge hole formed in the pathway feeder for allowing the inflation gas to be discharged from the inflation chamber to the inflow gas inflow passage. .

Further, the movement path providing unit is formed in a tubular shape having a hollow portion, and inflation gas flows into the expansion chamber through the hollow portion.

And the connecting portion is closely connected to the inflation gas inflow passage side from the inside of the inflating chamber.

And the vortex prevention part is located at an edge of the expansion chamber.

And the discharge hole is located adjacent to the connection portion. Further, the connection portion is formed with a plurality of fastening holes along the edge thereof.

Further, one end of the moving path providing member on the side of the expansion chamber is formed to be inclined outward.

And the connecting portion is formed in a plate shape.

And the connection portion is formed with a vortex prevention portion bent toward the expansion chamber along the circulation path of the inflation gas.

As described above, in the gas-insulated switchgear for a gas insulated switchgear according to the present invention, the vortex prevention part provided at the connection part is formed not only to be bent, but also to be positioned at the corner side where the vortex is generated, So that the mixing efficiency of the hot gas and the cold gas is improved.

Further, a flow path providing portion is formed in the connecting portion, so that the flow of the hot gas is regulated to a regular state and then flows into the expansion chamber, thereby improving the mixing efficiency of the hot gas and the cold gas.

In addition, by improving the mixing efficiency of the hot gas and the cold gas, the hot gas having a high temperature and a low density is discharged to the arc side in a state of being changed into a low temperature and high density heat gas, .

Further, one end of the travel path providing portion is formed so as to be tilted outward, thereby increasing the mixing efficiency of the hot gas and the cold gas by increasing the amount of the hot gas introduced into the expansion chamber.

In addition, at least one discharge hole is formed in the moving path providing portion so that the mixed inflation gas in the expansion chamber can be discharged smoothly without being disturbed by the movement path providing portion when discharged to extinguish the arc.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a conceptual view showing a conventional composite-type gas circuit breaker for a gas-insulated switchgear. FIG.
BACKGROUND OF THE INVENTION Field of the Invention [0001] The present invention relates to a gas-insulated switchgear for gas insulated switchgear.
3 is a conceptual diagram showing a process in which a thermal gas is mixed with a cold gas in an expansion chamber and then discharged in a conventional gas scrubber of a gas scrubber of a gas insulated switchgear.
Fig. 4 is a configuration diagram showing a conventional gas-insulated type gas circuit breaker for a gas-insulated switchgear.
5 is a block diagram showing a process in which inflation gas is circulated in an expansion chamber of a conventional gas-insulated switchgear for a gas insulated switchgear.
6 is a view showing a circulation process of an inflated gas in a state where a vortex prevention member is installed in an expansion chamber of a conventional compound gas recirculation type gas circuit breaker for a gas insulated switchgear.
7 is a detailed view showing a process in which inflation gas is circulated in a state where a vortex prevention member is not installed in an expansion chamber of a conventional gas-insulated switchgear for a gas insulated switchgear.
8 is a detailed view showing a process of circulating inflation gas in a state in which a vortex prevention member is installed in an expansion chamber of a conventional gas-insulated switchgear for a gas insulated switchgear.
FIG. 9 is a perspective view showing a vortex prevention member provided in a gas recirculation type gas circuit breaker for a gas insulated switchgear according to the present invention. FIG.
10 is a cross-sectional view showing a state in which a vortex prevention member is provided in a gas-insulated switchgear for a gas-insulated switchgear according to the present invention.
11 is a detailed view showing the circulation process of the inflating gas in the inflating chamber of the gas recirculation type gas circuit breaker for gas insulated switchgear according to the present invention.
12 is a cross-sectional view showing a state in which another vortex prevention member is provided in the expansion chamber of the composite COG type gas circuit breaker for a gas insulated switchgear according to the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Reference will now be made in detail to embodiments of the present invention, examples of which are illustrated in the accompanying drawings, wherein like reference numerals refer to the like elements throughout.

FIG. 9 is a perspective view of a vortex prevention member provided in a gas-insulated switchgear for a gas-insulated switchgear according to the present invention, and FIG. 10 is a perspective view showing a vortex- 11 is a detailed view showing a circulation process of the inflation gas in the expansion chamber of the gas-insulated switchgear for a gas insulated switchgear according to the present invention, and Fig. 12 is a cross- Sectional view showing a state in which another vortex prevention member is provided in the expansion chamber of the combined-extinguishing gas circuit breaker for the apparatus.

9 to 11, the gas circuit breaker 100 of the gas insulated switchgear according to the present invention includes a movable side contact 150, a fixed side contact 170 and a nozzle 190, The closing or closing state of the gas circuit breaker 100 is adjusted as the movable contact 150 contacts or separates from the fixed side contact 170. [

At this time, an arc is generated when the movable contact 150 and the fixed contact 170 are separated, and the inflation gas (thermal gas) generated thereby is passed through the inflation chamber inflow passage 210, And then mixed with the cold gas provided in the expansion chamber 110.

The inflated gas mixed with the cold gas while circulating in the inflating chamber 110 is injected into the inter-arc region through the inflow gas inflow passage 210 through the nozzle 190, so that the arc extinguishes.

In order to effectively extinguish the arc, the inflation gas must have a low temperature and a high density. However, since the inflation gas flowing into the expansion chamber 110 has a high temperature and a low density, The gas is mixed with a gas having a low temperature and a high density, and then sprayed to the arc side, the arc can be efficiently extinguished.

Therefore, in the expansion chamber 110 of the gas circuit breaker 100 of the present invention, the vortex prevention member 130 is provided to prevent vortex from being generated for smooth mixing of the inflation gas and the cold gas when the inflation gas is circulated.

The vortex prevention member 130 is provided inside the expansion chamber 110 to prevent vapors from being generated in the circulation of the inflation gas and to prevent the inflow gas from passing through the inflation gas inflow passage 210, The flow of inflation gas is allowed to flow into the expansion chamber 110 from a fully developed flow state by providing a movement path that can be moved a certain distance before being introduced into the inflow chamber 110.

At this time, the vortex prevention member 130 includes a connection part 131 and a movement path providing part 133.

The connecting portion 131 is formed in a plate shape and is connected to the inflation chamber inflow passage 210 in the inflating chamber 110 so that the vortex prevention member 130 is inserted into the inflator chamber 110 At the same time, the vortex is prevented from being generated when the inflation gas is circulated, thereby improving the mixing efficiency of the inflation gas and the cold gas.

A plurality of fastening holes 131b are formed along the edge of the connection part 131. A fastening member 230 such as a bolt is passed through the fastening hole 131b to connect the connection part 131 to the expansion chamber 110 As shown in FIG.

The connection portion 131 is formed with a vortex prevention portion 131a so as to be bent toward the expansion chamber 110 and the vortex prevention portion 131a prevents the connection portion 131 from being connected to the inside of the expansion chamber 110 And is positioned at an edge of the expansion chamber 110 when the expansion chamber 110 is closed.

That is, when the inflation gas circulates in the inflating chamber 110, a vortex is generated mainly in the vicinity of the corners to interfere with the mixing of the inflating gas and the cold gas. However, since the vortex prevention part 131a is disposed inside the inflating chamber 110 So that vortexes are prevented from being generated in the expansion chamber 110.

The movement path providing portion 133 is formed in a tubular shape having a hollow portion 133b and penetrating from the central portion of the connecting portion 131 to the expansion chamber 110 side so that the inflating gas can flow into the hollow portion 133b To the expansion chamber (110).

More specifically, when the inflation gas passes through the inflow gas inflow passage 210, the inflow gas flows in an irregular state due to the shape of a vortex or a vortex, and the flow is not regulated to a regular state If the refrigerant is introduced into the expansion chamber 110, mixing with the refrigerant gas is not smoothly performed.

Accordingly, by providing a movement path for allowing the inflation gas to move a certain distance through the movement path providing unit 133 before the inflation gas is introduced into the expansion chamber 110, the inflation gas is inflated while passing through the movement path providing unit 133 The flow of the gas is regularly controlled so that the inflow of the inflation gas into the inflating chamber 110 is smoothly performed with the cold gas.

At this time, at least one discharge hole 133a is formed in the movement path providing portion 133 so that the inflation gas is discharged from the inflation chamber 110 to the inflow gas inflow passage 210.

That is, the movement path providing unit 133 provides a moving path for moving the expansion gas to a certain distance before the inflow gas is introduced into the expansion chamber 110, but the inflation gas introduced into the expansion chamber 110 is mixed with the cooling gas And then discharged to the side of the inflation gas inflow passage 210, the discharge path may be obstructed by the movement path providing portion 133.

Accordingly, the plurality of discharge holes 133a are formed in the movement path providing portion 133 so that the inflation gas mixed with the cold gas is smoothly discharged to the inflation gas inflow passage 210 side through the discharge hole 133a. do.

The shape of the discharge hole 133a may be variously formed according to the magnitude of the breaking current and the discharge hole 133a may be positioned adjacent to the connection part 131 so that the inflation gas may flow into the discharge hole 133a And then discharged to the inflow gas inflow passage 210.

12, the other vortex prevention member 130 'included in the gas circuit breaker 100 of the gas insulated switchgear according to the present invention includes a connection portion 131', a movement path providing portion 133 ' At this time, one end of the movement path providing portion 133 'on the side of the expansion chamber 110 may be inclined outward.

Accordingly, a larger amount of inflation gas is introduced into the expansion chamber 110 when the inflation gas passes through the movement path providing portion 133 ', thereby allowing the inflation gas and the cooling gas to smoothly mix.

In the gas-insulated switchgear 100 for gas insulated switchgear according to the present invention constructed as described above, the vortex prevention part 131a provided in the connection part 131 is formed not only to be bent but also to be positioned at the corner side where the vortex is generated Thereby preventing a vortex from being generated in the circulation of the inflation gas, thereby improving the mixing efficiency of the hot gas and the cold gas.

The connecting portion 131 may be formed with a traveling path providing portion 133 for providing a traveling path through which the hot gas flows into the expansion chamber 110. When the heating gas passes through the traveling path providing portion 133, So that the flow of the heat gas is regulated to a regular state and then flows into the expansion chamber 110 to improve the mixing efficiency of the hot gas and the cold gas.

In addition, by improving the mixing efficiency of the hot gas and the cold gas, it is possible to mix the high temperature and low density heat gas with the low temperature and high density cold gas, and then to discharge it into the arc side Thereby effectively extinguishing the arc.

In addition, one end of the travel path feeder 133 is inclined outward to increase the amount of the heat gas flowing into the expansion chamber 110, thereby improving the mixing efficiency of the hot gas and the cold gas.

At least one discharge hole 133a is formed in the movement path providing portion 133 so that the obstruction of the travel path providing portion 133 when the inflation gas mixed in the expansion chamber 110 is discharged to extinguish the arc Ensure effective discharge without receiving.

While the invention has been shown and described with reference to certain preferred embodiments thereof, it will be understood by those skilled in the art that various changes and modifications may be made therein without departing from the spirit and scope of the invention as defined by the appended claims. Therefore, the above description does not limit the scope of the present invention, which is defined by the limitations of the following claims.

10: gas breaker 11: expansion chamber
13: main nozzle 15: auxiliary nozzle
17: fixed side contact point 19: movable side contact point
D1, D2, D3, D4, D5, D6: inflation gas circulation direction
W: Vortex 21: Anti-check valve
23, 130, 130 ': vortex prevention member
100: Gas breaker 110: Expansion chamber
131, 131 ': connection part 131a: vortex prevention part
131b: fastening holes 133, 133 '
133a: discharge hole 133b: hollow part
150: movable side contact point 170: fixed side contact point
190: nozzle 20, 210: inflation gas inflow passage
230: fastening member

Claims (9)

An expansion chamber in which inflation gas is introduced and circulated through the inflation gas inflow passage and a vortex prevention member provided inside the inflation chamber to prevent the generation of vortex,
The vortex prevention member
A connecting portion connected to the expansion chamber;
A movement path providing portion formed at the connection portion to the expansion chamber side to provide a movement path through which the inflation gas flows into the expansion chamber; And
At least one or more discharge holes formed in the movement path providing unit to allow the inflation gas to be discharged from the inflation chamber to the inflation gas inflow passage;
For a gas insulated switchgear The method according to claim 1,
The movement path providing unit,
Wherein the inflated gas flows into the expansion chamber through the hollow portion, wherein the inflated gas flows into the expansion chamber. The method according to claim 1,
Wherein the connecting portion is closely connected to the inflation gas inflow passage side in the inflating chamber. The method of claim 3,
And the vortex prevention portion is located at an edge of the expansion chamber. The method according to claim 1,
And the discharge hole is located adjacent to the connection portion. The method according to claim 3 or 4,
Wherein a plurality of fastening holes are formed along the edge of the connection portion. 6. The method according to any one of claims 1 to 5,
Wherein one end of the path of the travel path on the side of the expansion chamber is inclined outwardly. The method according to claim 1,
Wherein the connecting portion is formed in a plate shape. 9. The method of claim 8,
Wherein the connection portion is formed with a vortex prevention portion bent toward the expansion chamber along the circulation path of the inflation gas.

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