KR20130051208A - Breaking part with compressive thermal chamber of puffer type circuit breaker - Google Patents

Abstract

PURPOSE: A compression type thermal expansion room cut-out unit of a puffer type is provided to improve the operation stability and the SOHO performance by preparing the cylinder structured thermal expansion room which is supported by an elastomer and is able to compress. CONSTITUTION: A puffer cylinder(310) comprises a movable arc contact point(150), a movable main contact point(160), and a nozzle(170). A fixed contact(180) is installed facing the front of the puffer cylinder. The fixed contact comprises a fixed arc contact(184) and a fixed main contact(182). A thermal expansion room piston(320) is inserted inside the thermal expansion room. An elastomer(330) applies the pushing force to the nozzle direction on the thermal expansion room piston. A thermal expansion gas pipe(340) penetrates the thermal expansion room piston and is expanded to the inside of the thermal expansion room.

Description

Compression type thermal expansion chamber breaker of puffer type gas circuit breaker {BREAKING PART WITH COMPRESSIVE THERMAL CHAMBER OF PUFFER TYPE CIRCUIT BREAKER}

The present application relates to a compression type thermal expansion chamber blocking portion of the puffer-type gas circuit breaker, and more particularly, to a compression of the puffer-type gas circuit breaker having a compressible thermal expansion chamber having a cylindrical structure supported by an elastic body, and improved operation stability and arc extinguishing performance. It relates to a type thermal expansion chamber shield.

The breaker of a conventional puffer type breaker is composed of a fixed main contact, a fixed arc contact, a movable main contact, a movable arc contact, a nozzle, a puffer cylinder and a piston.

The breaker keeps the input state in which the fixed part and the moving part are in contact with each other in the normal state, but when the breakdown current flows due to an abnormality in the power system, the circuit breaker cuts off the circuit to protect the load and other electric equipment. to be. Looking at the driving method of the breaker, the movable part of the breaker is moved by the operation signal of the drive unit, whereby the gas inside the puffer cylinder is compressed by the piston, and the movable arc contact point and the fixed arc contact point are separated from each other as the movable part moves. An arc occurs between the two contacts. At this time, the generated arc is extinguished by SF ₆ gas compressed in the puffer cylinder, and the breaker interrupts the fault current when the insulation between the poles is restored.

1 and 2 are cross-sectional views showing the operation of the breaker 100 of the conventional puffer type circuit breaker. The left side shows the current breaking operation and the right side shows the current breaking operation completion state. 1 and 2, the block 100 of the conventional puffer type breaker includes a fixed piston 120, a puffer chamber 130 and a thermal expansion chamber 140, and has a movable arc contact at the front end ( 150 and a perforated cylinder 110 having a movable main contact point 160 and a nozzle 170 through which arc extinguishing gas is ejected or drawn in, and installed in front of the percylinder 110 and having a fixed arc contact point 184. And a fixed contact 180 having a fixed main contact 182. 1 shows a small current breaking time of the breaker 100 of a conventional puffer type breaker, and FIG. 2 shows a large current breaking time. Since the puffer chamber 130 and the thermal expansion chamber 140 of the blocking unit 100 of the conventional puffer type circuit breaker have a fixed volume, the nozzle 170 when the volume of the thermal expansion chamber 140 is large at the time of breaking the small current in FIG. 1. The low pressure of the arc extinguishing gas (SF ₆ ) is called between the) and the small current blocking performance is lowered, the pressure of the puffer chamber 130 is rapidly lowered, the impact on the drive due to the repulsion by the arc could be applied.

The present application provides a technique for keeping the volume of the thermal expansion chamber small by compressing the thermal expansion chamber that can ensure the reliability of the extinguishing performance of the puffer type circuit breaker.

The present application provides a technique for preventing the pressure of the puffer seal from being lowered quickly during the small current interruption, which can eliminate the impact on the drive unit by the repulsive force by the arc.

The present application provides a technique for extinguishing the extinguishing gas in the thermal expansion chamber that can improve the extinguishing performance of the puffer type circuit breaker without being discharged to the outside.

Among the embodiments, the compressed thermal expansion chamber block of the puffer-type gas circuit breaker includes a fixed piston, a puffer chamber and a thermal expansion chamber, and includes a nozzle at which a movable arc contact and a movable main contact and an extinguishing gas are ejected or drawn in. And a fixed contactor having a fixed arc contact point and a fixed main contact point which are installed to face the front of the puffer cylinder, and wherein the movable arc contact point and the movable main contact point point are formed by forward and backward movement of the puffer cylinder point. A puffer-type gas circuit breaker contacting or separated from an arc contact point and the fixed main contact point to prevent arcing by moving an arc extinguishing gas, wherein the nozzle includes a thermal expansion chamber piston inserted into the thermal expansion chamber and the thermal expansion chamber piston. An elastic body that acts as a pushing force, and passes through the thermal expansion chamber piston to the interior of the thermal expansion chamber. A gas inlet formed at a front end of the thermally expanding gas pipe and the thermally expanding gas pipe, the check valve for guiding the arc extinguishing gas into the thermally expanding chamber, and a gaseous outlet formed at the rear of the thermally expanding chamber piston to be allowed to enter and exit the thermally expanding chamber. It includes.

In one embodiment, the elastic body is compressed during the large current blocking operation of the puffer-type gas circuit breaker to increase the volume of the thermal expansion chamber, and relaxes when the puffer-type gas circuit breaker completes the large current blocking operation, the arc inside the thermal expansion chamber Sex gas can be released to the outside. In another embodiment, the puff-type gas circuit breaker provided with the compression type thermal expansion chamber is provided with a first thermal expansion check valve for guiding the arc extinguishing gas from the outside to the thermal expansion chamber at the gas inlet, and the thermal expansion chamber piston with the The apparatus may further include a second thermal expansion check valve configured to guide the extinguishing gas from the rear space of the thermal expansion chamber piston to the front space. In another embodiment, the arc extinguishing gas behind the thermal expansion chamber piston may be moved to the front space of the thermal expansion chamber piston through the second thermal expansion check valve during the large current blocking operation of the puffer-type gas circuit breaker.

The disclosed technology of the present application can keep the volume of the thermal expansion chamber compressed to keep the volume of the thermal expansion chamber small so that the pressure of the extinguishing gas, which is called as a nozzle, does not decrease significantly, thereby ensuring the reliability of the extinguishing performance of the puffer type circuit breaker.

The disclosed technology of the present application can improve the extinguishing performance of the puffer type circuit breaker against the small current by preventing the pressure from rising due to the large space of the puffer seal during the small current interruption.

1 and 2 are cross-sectional views showing the operation of the breaker of the conventional puffer type breaker.
3 and 4 are cross-sectional views showing the operation of the compressed thermal expansion chamber blocking unit of the puffer-type gas circuit breaker according to an embodiment of the disclosed technology.
5 and 6 are cross-sectional views showing the operation of the compressed thermal expansion chamber blocking unit of the puffer-type gas circuit breaker according to another embodiment of the disclosed technology.

The description of the disclosed technique is merely an example for structural or functional explanation and the scope of the disclosed technology should not be construed as being limited by the embodiments described in the text. That is, the embodiments may be variously modified and may have various forms, and thus the scope of the disclosed technology should be understood to include equivalents capable of realizing the technical idea. In addition, the objects or effects presented in the disclosed technology does not mean that a specific embodiment should include all or only such effects, and thus the scope of the disclosed technology should not be understood as being limited thereto.

Meanwhile, the meaning of the terms described in the present application should be understood as follows.

The terms "first "," second ", and the like are intended to distinguish one element from another, and the scope of the right should not be limited by these terms. For example, the first component may be referred to as a second component, and similarly, the second component may also be referred to as a first component.

It is to be understood that when an element is referred to as being "connected" to another element, it may be directly connected to the other element, but there may be other elements in between. On the other hand, when an element is referred to as being "directly connected" to another element, it should be understood that there are no other elements in between. On the other hand, other expressions describing the relationship between the components, such as "between" and "immediately between" or "neighboring to" and "directly neighboring to", should be interpreted as well.

It should be understood that the singular " include "or" have "are to be construed as including a stated feature, number, step, operation, component, It is to be understood that the combination is intended to specify that it does not preclude the presence or addition of one or more other features, integers, steps, operations, elements, components, or combinations thereof.

All terms used herein have the same meaning as commonly understood by one of ordinary skill in the art unless otherwise defined. Commonly used predefined terms should be interpreted to be consistent with the meanings in the context of the related art and can not be interpreted as having ideal or overly formal meaning unless explicitly defined in the present application.

3 and 4 are cross-sectional views showing the operation of the compressed thermal expansion chamber blocking unit of the puffer-type gas circuit breaker according to an embodiment of the disclosed technology.

Here, FIG. 3 shows a small current interruption, FIG. 4 shows a large current interruption, the left side of each drawing shows a state in which a current blocking operation is being performed, and the right side shows a current blocking operation completion state.

Referring to FIGS. 3 and 4, the compression type thermal expansion chamber blocking unit 300 of the puffer-type gas circuit breaker includes a puffer cylinder 310, a fixed contactor 180, a thermal expansion piston 320, an elastic body 330, and a thermal expansion gas pipe ( 340, check valve 350 and gas inlet 360.

The puffer cylinder 310 includes a fixed piston 120, a puffer chamber 130, and a thermal expansion chamber 140, and the movable arc contact 150, the movable main contact 160, and the extinguishing gas are blown out at a front end thereof. It has a nozzle 170 to be introduced.

The fixed contact 180 is installed to face the front of the puffer cylinder 310 and includes a fixed arc contact 184 and a fixed main contact 182.

In the compression type thermal expansion chamber blocking unit 300 of the puffer-type gas circuit breaker, the movable arc contact 150 and the movable main contact 160 are connected to the fixed arc contact 184 and the fixed main contact by the back and forth of the puffer cylinder 310. 182 is in contact with or separated and the arc extinguishing gas moves to prevent arcs that occur between the fixed arc contact 184 and the movable arc contact 150 when they are separated. In one embodiment, when the circuit is in steady state, the fixed arc contact 184 is inserted in contact with the inside of the movable arc contact 150, and the movable main contact 160 is in contact with the inside of the fixed main contact 182. And is inserted, the current is energized to the fixed arc contact 184, the fixed main contact 182, the movable arc contact 150 and the movable main contact 160. In one embodiment, the extinguishing gas may be implemented with SF ₆ insulation gas.

The thermal expansion piston 320 is installed in a structure that can be inserted into the interior of the thermal expansion chamber 140 to maintain the gas pressure therein.

The elastic body 330 is a device that applies a force pushing the thermal expansion chamber piston 320 in the direction of the nozzle 170. In an embodiment, the elastic body 330 may be installed between the partition wall between the puffer chamber 130 and the thermal expansion chamber 140 and the thermal expansion chamber piston 320, and may be implemented as a device having elastic force such as a spring and a piston. have.

The thermal expansion gas pipe 340 passes through the thermal expansion chamber piston 320 and extends into the thermal expansion chamber 140.

The check valve 350 is provided at the front end of the thermal expansion gas pipe 340 to guide the extinguishing gas to the thermal expansion chamber 140. In other words, the check valve 350 allows one direction to pass the arc extinguishing gas in the direction of the thermal expansion chamber 140.

The gas inlet and outlet 360 is formed to allow the extinguishing gas at the rear of the thermal expansion chamber piston 320 to enter and exit the thermal expansion chamber 140.

In FIG. 3, when the small current is blocked, the puffer cylinder 310 retreats, and the arc extinguishing gas in the puffer chamber 130 flows into the thermal expansion chamber 140 through the thermal expansion gas pipe 340 and the check valve 350. The extinguishing gas of the introduced thermal expansion chamber 140 is blown between the movable arc contact 150 and the fixed arc contact 184 from the nozzle 170. Herein, the elastic body 330 may maintain the volume of the thermal expansion chamber 140 so that the amount of the extinguishing gas is not greatly reduced. In addition, the pressure of the puffer chamber 130 can be prevented from being lowered quickly, thereby preventing the impact applied to the driving unit due to the repulsive force due to the arc.

In FIG. 4, when the extinguishing gas is expanded by the arc heat between the fixed arc contact 184 and the movable arc contact 150, the thermal expansion chamber piston 320 increases the volume of the thermal expansion chamber 140 so that the extinguishing gas is released. It is drawn into the thermal expansion chamber 140 and flows between the movable arc contact 150 and the fixed arc contact 184. Here, the elastic body 330 is compressed during the large current blocking operation of the puffer-type gas circuit breaker 300 to increase the volume of the thermal expansion chamber 140, and relaxes when the puffer-type gas circuit breaker 300 completes the large current blocking operation. The extinguishing gas inside the chamber 140 is discharged to the outside.

5 and 6 are cross-sectional views showing the operation of the compressed thermal expansion chamber blocking unit of the puffer-type gas circuit breaker according to another embodiment of the disclosed technology.

Here, FIG. 5 shows a small current interruption, FIG. 6 shows a large current interruption, the left side of each figure shows a state in which a current interruption operation is being performed, and the right side shows a current interruption operation completion state.

5 and 6, in another embodiment, the compressed thermal expansion chamber blocking unit 500 of the puffer-type gas circuit breaker further includes a first thermal expansion check valve 510 and a second thermal expansion check valve 520. do.

The first thermal expansion check valve 510 is installed at the gas inlet and outlet 360 shown in FIGS. 3 and 4 to guide the extinguishing gas from the outside to the thermal expansion chamber 140.

The second thermal expansion check valve 520 is installed through the thermal expansion chamber piston 320 and guides the extinguishing gas from the rear space of the thermal expansion chamber piston 320 to the front space.

In one embodiment of FIG. 6, the arc extinguishing gas at the rear of the thermal expansion chamber piston 320 during the high current blocking operation of the puffer-type gas circuit breaker 500 passes through the thermal expansion chamber piston through the second thermal expansion check valve 520. It may be moved to the front space of 320. Thus, the extinguishing gas in the rear space of the thermal expansion chamber piston 320 may be utilized, and thus the extinguishing performance may be improved when the large current blocking of the puffer type circuit breaker 500 is interrupted.

It will be apparent to those skilled in the art that various modifications and variations can be made to the present invention without departing from the spirit and scope of the present invention as set forth in the following claims It can be understood that

300, 500: compression type thermal expansion chamber blocking part 310: puffer cylinder
320: side expansion chamber piston (Piston) 330: elastic body
340: thermal expansion gas pipe 350: check valve
360: gas entrance 120: piston
130: Puffer Chamber 140: thermal expansion chamber
150: movable arc contact 160: movable main contact
170: nozzle 180: fixed contactor
182: fixed main contact 184: fixed arc contact
510: first thermal expansion check valve 520: second thermal expansion check valve

Claims (4)

A percussion cylinder comprising a fixed piston, a puffer seal and a thermal expansion chamber, having a movable arc contact and a movable main contact at the front end, and a nozzle through which extinguishing gas is ejected or introduced; And a fixed contact having a contact and a fixed main contact, wherein the movable arc contact and the movable main contact are contacted or separated from the fixed arc contact and the fixed main contact by forward and backward of the puffer cylinder. In the puffer-type gas circuit breaker to prevent the arc by moving,
A thermal expansion chamber piston inserted into the thermal expansion chamber;
An elastic body that exerts a pushing force on the thermal expansion chamber piston in the nozzle direction;
A check valve provided at a front end of the thermal expansion gas pipe and the thermal expansion gas pipe extending through the thermal expansion chamber piston and extending into the thermal expansion chamber, for guiding the arc extinguishing gas to the thermal expansion chamber; And
Compression-type thermal expansion chamber blocking portion of the puffer-type gas circuit breaker including a gas inlet is formed so that the arc extinguishing gas at the rear of the thermal expansion chamber piston is allowed to enter and exit the thermal expansion chamber. 2. The absorbent article according to claim 1, wherein the elastic body
During the large current blocking operation of the puffer-type gas circuit breaker is compressed to increase the volume of the thermal expansion chamber,
Compression-type thermal expansion chamber breaker of the puffer-type gas circuit breaker characterized in that to relax when the puffer-type gas circuit breaker completes the large current blocking operation to discharge the extinguishing gas inside the thermal expansion chamber to the outside. According to claim 1, wherein the puff-type gas circuit breaker provided with the compression type thermal expansion chamber
A first thermal expansion check valve is provided at the gas inlet and outlet to guide the arc extinguishing gas to the thermal expansion chamber from outside.
And a second thermal expansion check valve for guiding the arc extinguishing gas from the rear space of the thermal expansion chamber piston to the front space of the thermal expansion chamber piston. 4. The extinguishing gas of claim 3, wherein the extinguishing gas at the rear of the thermal expansion chamber piston is
Compression type thermal expansion chamber breaker of the puffer-type gas circuit breaker characterized in that it is moved to the front space of the thermal expansion chamber piston through the second thermal expansion check valve during the large current blocking operation of the puffer-type gas circuit breaker.

Images