KR20120002779A - Hybrid extinction type gas circuit breaker for gas - Google Patents

Abstract

PURPOSE: A hybrid-extinction type gas circuit breaker for gas insulated switchgear is provided to eliminate an arc in a gap by spraying extinction gas with the automatic movement of a movable valve with a pressure difference. CONSTITUTION: A fixing unit(10) includes an arc contact point part of the fixing unit. A piston(22) is included in a cylinder(21). A puffer room(24) is formed with a partition wall. An operation rod(26) includes the arc contact point part of the fixing unit and the arc contact point part(26a) of a moving part which is approachable. An attaching part adheres closely to the partition wall while being movable by pressure difference. A movable part opens and closes a thermal expansion room(25) while an operation rod(26) is penetrated. A discharge hole is formed to discharge the extinction gas in an puffer room(24).

Description

Hybrid Extinction Type Gas Circuit Breaker for Gas Insulated Switchgear

The present invention relates to a complex arc-type gas circuit breaker for a gas insulated switchgear, and more particularly, it is possible to reliably remove the arc when the fault current is blocked without the pressure loss of the arc extinguishing gas.

In general, a gas insulated switchgear is composed of a circuit breaker, a current transformer, a line disconnector / earth breaker, a bus disconnector / ground breaker, etc., and a gas circuit breaker installed on a transmission line opens and closes for inspection of equipment and lines in a normal state. In operation, when an error occurs in the transmission line, it serves to protect the line and the load by blocking the fault current.

In addition, a gas circuit breaker, which is a device for blocking a fault current, uses gas for extinguishing, and extinguishes an arc generated between two contacts through the gas.

These gas circuit breakers are classified into a paper type, a rotary arc type, a thermal expansion type, a hybrid type extinction type, etc. according to the type of arc extinguishing. Conventional gas circuit breakers use SF ₆ gas as the extinguishing gas.

Among the above, the popper extinguishing method is a method of extinguishing arcs while compressing the extinguishing gas in the compression chamber in the blocking unit by using an external driving force to blow the compressed gas between the poles by using an external driving force. The method accumulates (heats up the pressure) the arc heat generated when the fault current is interrupted, and blows the pressure increased by accumulated heat to the gap. The method is a compound SO method.

 Here, in the case of the hydraulic and pneumatically driven gas circuit breakers (mainly applied to the paper type blocking method), a driving part and a high breaking speed are required to cause mechanical defects of the gas circuit breaker, an increase in the size of the breaker, and an increase in product cost. .

Therefore, a hybrid extinguishing type blocking method has been developed that can perform ultra-high voltage and high current interruption at a lower speed using a small driving force (driving force by a motor-spring). 1, the fixed part 10 and the movable part 20 are formed as shown in FIG. 1, and the fixed part 10 is provided in the shield 11 and the shield 11. The fixed part main contact part 12 and the fixed part arc contact part 13 located in the center of this fixed part main contact part 12 are comprised.

In addition, the movable part 20 is formed with a cylinder 21, a piston 22 provided while maintaining a fixed state inside the cylinder 21, and a partition wall 23 therebetween so that the gas for extinguishing It consists of a papper chamber 24 and a thermal expansion chamber 25 to be filled.

In addition, the movable part 20 of the conventional gas circuit breaker is provided with an operating rod 26 that penetrates the inside of the piston 22 and extends to the end of the cylinder 21, and the cylinder is an end position of the operating rod 26. The nozzle part 27 is engaged and extended by the edge part of 21. As shown in FIG.

Moreover, the movable part arc contact part 26a is formed in the edge part of the operation rod 26 of the movable part 20. As shown in FIG.

Moreover, the discharge hole 22a is formed in the end surface of the said piston 22, and the safety valve 22b is provided in this discharge hole 22a. In addition, a discharge hole 23a is formed in the partition 23, and the discharge hole 23a is provided with a check valve 23b.

Meanwhile, as another structure, as shown in FIG. 2, instead of forming the partition 23 in the cylinder 21 by changing the structure of the movable part 20, the sleeve 28 is formed to form a papper seal ( 24 and the thermal expansion chamber 25 is in communication.

In the conventional composite arc-type gas circuit breaker having such a structure, when the movable portion 20 is separated from the fixed portion 10 at the initial stage of the breaking operation or during the low current interruption, the cylinder 11 is fixed by the fixed piston 22. The inside of the papillary chamber 24 is compressed to increase the pressure. Then, the check valve 23a provided in the partition 23 is opened, and the compressed SOHO gas SF ₆ contained in the papillary 24 is opened in the thermal expansion chamber ( 25, the arc generated between the movable part arc contact portion 26a and the fixed portion arc contact portion 13 of the operation rod 26 is removed (excited action).

In the large current interruption, since the arc generated between the poles is large, the pressure increases as much heat accumulates in the thermal expansion chamber 25, and thus the arc is removed by a high-pressure extinguishing gas.

Since the conventional arc extinguishing type gas circuit breaker has a structure in which the compressed extinguishing gas from the papillary 24 must pass through the thermal expansion chamber 25, a phenomenon in which the pressure of the extinguishing gas is lowered occurs and the fault current is blocked. There was a problem that results in performance degradation.

In addition, as shown in FIG. 2, even when the parallel type extinguishing type gas circuit breaker has a structure, the compressed extinguishing gas of the papper chamber 24 passes through the sleeve 28 to the thermal expansion chamber 25 and the nozzle unit 27. Since it passes in the direction of ()), arc extinguishing gas does not remove the arc which generate | occur | produces in the nozzle part 27 effectively.

The present invention is to solve the above-mentioned conventional problems, it is to enable the gas to be ejected by separating the papper chamber and the thermal expansion chamber according to the fault current blocking condition through the movable valve body.

The problem solving means of the present invention and the fixing portion having a fixed portion arc contact portion; A cylinder, a piston provided inside the cylinder, a papillar and a thermal expansion chamber formed by a partition wall, and an actuating rod having a movable portion arc contact portion which is close to the fixed portion arc contact portion through the inside of the piston and the cylinder. As a complex extinguishing gas breaker for a gas insulated switchgear composed of a movable part,

One side of the partition wall is a structure provided with a movable valve including a close contact with the partition wall while being movable by the pressure difference, and a moving part for opening and closing the thermal expansion chamber while the operation rod penetrates.

In addition, the close contact portion constituting the movable member is formed with a discharge hole for discharging the SOHO gas in the popper chamber, a check valve is coupled to the discharge hole, the through hole is formed in the moving part.

In addition, the thermal expansion chamber is formed with a discharge hole for discharging the SOHO gas in the direction of the fixed portion, which is one side of the thermal expansion chamber, a check valve is provided in the discharge hole, the support tube for sliding the movable part of the movable valve Is formed, the discharge hole is opened and closed by the moving portion of the movable valve is formed.

As described above, the present invention allows the movable valve to move automatically and inject the arc extinguishing gas by the pressure difference at the time of the fault current, that is, when the small current, the medium current, or the large current is interrupted, thereby removing the arc. In the blocking operation, it is possible to reliably remove the arc by injecting the elevated compressed SOHO gas into the gap between the nozzles without pressure loss.

1 is a view showing an example of a conventional complex arc-type gas circuit breaker (serial type).
2 is a view showing an example of a conventional complex arc-type gas circuit breaker (parallel type).
3 is a view showing an example of the complex extinguishing gas circuit breaker of the present invention.
4 is a diagram illustrating a state in which the complex extinguishing type gas circuit breaker of the present invention operates when the fault current is a small current.
5 is a diagram illustrating a state in which the complex extinguishing type gas circuit breaker of the present invention operates when the fault current is a large current.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

The same components as in the prior art will be described with the same reference numerals, and detailed description thereof will be omitted, and new components will be described in detail with the new reference numerals.

3 is a view showing an example of the complex extinguishing type gas circuit breaker according to the present invention. As shown in the figure, the movable valve 30 is provided on one side of the partition 23 to be movable.

The movable valve 30 has a close contact portion 31 in close contact with the partition 23 and a moving portion 32 extending from the close contact portion 31 to form a tubular (or sleeve) shape so that the operation rod 26 can pass therethrough. ), The close contact portion 31 has one or more discharge holes 31a formed in the circumferential direction, and has a structure in which a check valve 31b is coupled to the discharge hole 31a.

In addition, a moving hole 32a is formed in the moving part 32, and is formed in a tubular shape made of a cylindrical shape, and is coupled to be movable along the outer circumferential surface of the operation rod 26.

Moreover, the discharge hole 25a and the check valve 25b are provided in the one surface of the thermal expansion chamber 25, ie, the fixed part 10 direction.

In addition, the thermal expansion chamber 25 is formed with a support tube 25c for allowing the movable portion 32 of the movable valve 30 to be slidably movable, and has a discharge hole 25d opened and closed by the movable portion 32. Structure.

In the present invention having such a structure, as shown in FIG. 4, when the fault current of the load current or the small current is to be blocked, the movable part 20 is separated from the fixed part 10 by the driving part (not shown). When an arc occurs between the gap between the fixed portion arc contact portion 13 and the movable portion arc contact portion 26a, the pressure in the popper chamber 24 formed in the cylinder 21 is higher than the pressure in the thermal expansion chamber 25. Since it is high, the movable valve 30 provided in one side of the partition 23 moves to the right side on the drawing along the outer surface along the longitudinal direction of the operation rod 26. As the movable valve 30 moves, the discharge hole 25d formed in the support pipe 25c of the thermal expansion chamber 25 is blocked, and the check valve 31b formed in the close contact portion 31 of the movable valve 30 is opened. do.

Accordingly, the SOHO gas contained in the popper chamber 24 passes through the open check valve 25a and moves between the moving part 32 and the operation rod 26 of the movable valve 30 to be sprayed, thereby providing a nozzle unit. The arc is removed by extinguishing an interpolar position between the 27 and the fixed arc contact portion 13.

On the other hand, when the large current is interrupted, as shown in Fig. 5, since the arc generated between the poles is large, the pressure is increased while a large amount of arc heat is accumulated in the thermal expansion chamber 25. At this time, since the pressure in the thermal expansion chamber 25 becomes higher than the pressure in the popper chamber 24, the movable valve 30 moves to the left side and comes into close contact with the partition 23. Then, while the discharge hole 25d of the thermal expansion chamber 25 is opened, the arc extinguished gas is quickly discharged and sprayed, and the check valve 25b provided at one side of the thermal expansion chamber 25 is also opened while the arc extinguishing gas is opened. Is discharged to remove the arc formed between the poles.

At this time, the pressure in the popper chamber 24 is smaller than the pressure in the thermal expansion chamber 25 due to the operation of the drive unit, but it continuously rises, so when the pressure exceeds the predetermined pressure, the safety valve 22a provided in the piston 22 is opened. The pressure is lowered as it passes through the discharge hole (22a).

In addition, when the medium current (the current magnitude is higher than the pressure in the thermal expansion chamber 25 when the pressure on the papper chamber 24 becomes the current zero when the short circuit is blocked), an arc is generated and has a high pressure. The movable valve 30 moves in the direction of the popper chamber 24 to open the discharge hole 25d of the thermal expansion chamber 25 to accumulate pressure in the thermal expansion chamber 25, and at the time of zero zero current, the movable valve The check valve 25b in which the extinguishing gas compressed in the thermal expansion chamber 25 is formed in the thermal expansion chamber 25 is blocked by the discharge hole 25d of the thermal expansion chamber 25 while the 30 is moved toward the thermal expansion chamber 25 side. Is opened, and the compressed SOHO gas in the thermal expansion chamber 25 is injected toward the nozzle unit 27 to remove the arc at the interpolar position.

Although the present invention has been described for the embodiments of the present invention based on the accompanying drawings for convenience, various modifications and variations are possible without departing from the scope of the technical idea of the present invention, and such variations and modifications are claimed in the claims of the present invention. It is obvious that it is included in the scope.

10: fixed part
11: shield
12: fixed part main contact part
13: fixed part arc contact part
20: moving part
21: cylinder
22: piston
22a: discharge hole
22b: safety valve
23: bulkhead
23a: discharge hole
23b: check valve
24: popper seal
25: thermal expansion chamber
25a: discharge hole
25b: check valve
25c: support plate
25d: discharge hole
26: load operation
26a: Arc contact part of movable part
27 nozzle part
28: sleeve
30: movable valve
31: close contact
31a; Vent hole
31b: check valve
32: children's department
32a: through hole

Claims (3)

A fixed portion 10 having a fixed portion arc contact portion 13;
The cylinder 21, the piston 22 provided in the cylinder 21, the papper chamber 24 and the thermal expansion chamber 25 formed by the partition 23, the inside of the piston 22, Composite extinguishing type for gas insulated switchgear comprising a movable part 20 consisting of a working rod 26 having a movable part arc contact part 26a which is close to the fixed part arc contact part 13 by passing through a cylinder 21. As a gas circuit breaker,
One side of the partition 23 is movable part for opening and closing the thermal expansion chamber 25 while allowing the contact portion 31, which is in close contact with the partition 23 while moving by the pressure difference, and the operation rod 26 to penetrate ( 32. A combined extinguishing type gas circuit breaker for a gas insulated switchgear, comprising: a movable valve;
The method according to claim 1,
In the close contact portion 31 constituting the movable member 30, a discharge hole 31a for discharging the SOHO gas in the paper chamber 24 is formed, and a check valve 31b is coupled to the discharge hole 31a. And the through hole (32a) is formed in the moving part (32).
The method according to claim 1,
The thermal expansion chamber 25 is formed with a discharge hole (25a) for discharging the SOHO gas toward the fixed portion 10, which is one side of the thermal expansion chamber (25), the check valve (25b) in the discharge hole (25a) Is provided, the support pipe (25c) is formed to allow the movable portion 32 of the movable valve 30 to be slidable, the discharge hole (25d) opened and closed by the movable portion 32 of the movable valve 30 Composite SOHO type gas circuit breaker for gas insulated switchgear, characterized in that formed.

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