KR102466938B1 - Gas circuit breaker for gas insulation switchgear - Google Patents

Abstract

The present invention installs a partition wall inside the movable part support and prevents the arc gas discharged through the arc gas discharge hole from flowing into the compression chamber and the expansion chamber through the partition wall, so that the low-temperature arc gas in the expansion chamber is separated from the high-temperature arc gas. It has the effect of preventing the deterioration of the arc extinguishing performance due to mixing.

Description

Gas circuit breaker for gas insulated switchgear {GAS CIRCUIT BREAKER FOR GAS INSULATION SWITCHGEAR}

The present invention relates to a gas circuit breaker for a gas insulated switchgear, and more particularly, to a gas circuit breaker for a gas insulated switchgear with improved arc extinguishing performance and interruption performance.

In recent years, substations and the like have adopted many gas insulated switchgear (GIS) using sulfur hexafluoride gas (SF ₆ ) having high insulation among switchgear constituting high voltage substation facilities.

Gas insulated switchgear is a power device used for opening and closing or grounding high-voltage lines from thousands of volts to tens of thousands of volts in power transmission, transformation, and large-scale distribution power systems, branching of lines, and monitoring. It is a switchgear in which an opening and closing device is housed in a tank filled with an insulating gas such as sulfur hexafluoride (SF ₆ ) for arc extinguishing and electrical insulation between poles of alternating current.

Such a gas insulated switchgear is usually filled with SF ₆ gas and in a sealed container, a bushing (BS), a gas circuit breaker (CB), a disconnecting switch (DS), an earth switch (Earth Switch; ES), current transformer (Cureent transformer: CT) (12), etc.

On the other hand, FIG. 1 shows a configuration diagram showing a case in which a gas circuit breaker provided in a conventional gas insulated switchgear is in an input state, and in FIG. 2, a gas circuit breaker provided in a conventional gas insulated switchgear is in an off state. A configuration diagram showing the time is shown.

As shown in FIGS. 1 and 2, the conventional gas circuit breaker for gas insulated switchgear is divided into two parts: a movable part 40 and a fixed part 20, in which the movable part 40 has a movable part arc contact 43b, A cylinder 41, a cylinder rod 43 having an arc gas discharge hole 43a, etc. are provided, and the fixed part 20 has a fixed part arc contact 21 that contacts or separates the movable part arc contact 43b. are provided

Here, a compression chamber 45 and an expansion chamber 47 are provided inside the cylinder 41, and an insulating gas is filled inside the compression chamber 45. When the gas circuit breaker 10 is closed, the arc contact 43b of the movable part and the arc contact 21 of the fixed part remain in contact with each other, thereby conducting a load current.

In addition, when the fault current occurs and the cut-off (OPEN) state occurs, the movable part arc contact 43b and the fixed part arc contact 21 are separated to generate high-temperature arc gas, and some of the high-temperature arc gas is in the expansion chamber ( 47), it is discharged back to the fixed part 20, and the arc extinguishing action is performed on each contact point, and some is discharged to the outside through the movable part gas outlet 49 of the movable part 40.

However, in the conventional gas circuit breaker for gas insulated switchgear, the high-temperature arc gas generated when each contact is cut off passes through the arc gas discharge hole 43a and is discharged to the outside through the moving part gas discharge port 49, and the compression chamber ( 45) and the expansion chamber 47, it is mixed with the low-temperature arc gas in the expansion chamber 47, and then discharged to each contact point, thereby significantly reducing the blocking performance of the gas circuit breaker 10.

In addition, when the arc gas is introduced into the compression chamber 45 during the blocking operation of the gas circuit breaker 10, when the cylinder 41 provided in the movable part 40 moves in the direction away from the blocking position, that is, the fixed part 20, the compression chamber ( 45) is pressurized in the opposite direction to the direction of movement due to the pressure of the arc gas filled in, which causes fluctuations in the stroke applied when the cylinder 41 moves, resulting in a significant decrease in the blocking performance of the gas circuit breaker 10 there was

The present invention has been made to solve the problems described above, and an object thereof is to provide a gas circuit breaker for a gas insulated switchgear with improved arc extinguishing performance and blocking performance.

The object of the present invention described above, the fixed arc contact formed on the fixed support; A cylinder equipped with a compression chamber; a cylinder rod that moves according to the movement of the cylinder; a movable part arc contact formed on the cylinder rod to contact or separate from the fixed part arc contact; In the gas circuit breaker for a gas insulated switchgear including an arc gas discharge hole formed in the cylinder rod to discharge arc gas, the arc gas discharge hole is located spaced apart from the compression chamber toward the movable part inside the movable part support. It is characterized in that a barrier rib is formed to prevent the arc gas discharged through the inflow into the compression chamber.

In addition, the bulkhead is characterized in that it is formed to be bent toward the cylinder rod from the movable part support.

In addition, an open portion may be formed between the partition wall and the compression chamber of the movable part support so that external arc gas flows into the compression chamber.

In addition, a support for supporting the movement of the cylinder rod is formed on one surface of the partition wall on the side of the cylinder rod so as to be bent toward the movable part.

In addition, a guide portion for guiding external arc gas to flow into the compression chamber is formed on one surface of the partition wall on the compression chamber side.

In addition, the guide portion is characterized in that it is formed round.

In addition, when the gas circuit breaker is in an input state, one end of the compression chamber side of the guide part is characterized in that it is located closer to the compression chamber than the arc discharge hole.

As described above, the gas circuit breaker for the gas insulated switchgear installs a partition wall inside the movable part support and prevents the arc gas discharged through the arc gas discharge hole from flowing into the compression chamber and the expansion chamber through the partition wall, thereby preventing the low temperature of the expansion chamber. There is an effect of preventing arc gas from being mixed with high-temperature arc gas to prevent deterioration of arc extinguishing performance.

In addition, by forming an opening in the movable part support and allowing the low-temperature arc gas through the opening to flow into the expansion chamber after passing through the compression chamber, the effect of improving the arc extinguishing performance by increasing the amount of low-temperature arc gas in the expansion chamber have.

In addition, by forming a support at one end of the bulkhead, there is an effect of preventing the cylinder rod from shaking during movement when moving in the direction opposite to the fixing part or the fixing part.

In addition, by forming a round guide on one side of the bulkhead, there is an effect of smoothly introducing low-temperature arc gas from the outside of the gas circuit breaker into the compression chamber through the guide.

In addition, one end of the guide is located closer to the compression chamber than the arc gas discharge hole, so that some arc gas is prevented from being discharged between the bulkhead and the compression chamber through the arc gas discharge hole when switching from the input state to the cut-off state. have.

1 is a configuration diagram showing when a gas circuit breaker provided in a conventional gas insulated switchgear is in an input state.
Figure 2 is a configuration diagram showing when a gas circuit breaker provided in a conventional gas insulated switchgear is in a cut-off state.
3 is a configuration diagram showing a gas circuit breaker for a gas insulated switchgear according to the present invention in an input state.
Figure 4 is a configuration diagram showing a gas circuit breaker for a gas insulated switchgear according to the present invention is in a blocking state.
Figure 5 is a configuration diagram showing a state when the gas insulated switchgear according to the present invention is in the input state in the state provided with a guide portion in the gas circuit breaker.
Figure 6 is a configuration diagram showing a state when the gas insulated switchgear for the gas circuit breaker according to the present invention is in a blocking state with a guide provided.

Hereinafter, a gas circuit breaker for a gas insulated switchgear according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

Figure 3 is a configuration diagram showing when the gas circuit breaker for gas insulated switchgear according to the present invention is in the input state, Figure 4 is a configuration diagram showing when the gas circuit breaker for gas insulated switchgear according to the present invention is in the off state 5 is a configuration diagram showing a state in which a guide unit is provided in a gas circuit breaker for a gas insulated switchgear according to the present invention and is in an input state, and FIG. 6 is a guide to a gas circuit breaker for a gas insulated switchgear according to the present invention It is a configuration diagram showing the case of being in the blocking state in the state in which the unit is provided.

As shown in Figures 3 and 4, the gas circuit breaker for gas insulated switchgear according to the present invention moves according to the application of the fixing part 110 and the fault current, and is in contact with or separated from the fixing part 110 It includes a movable part 140 that adjusts the gas circuit breaker 100 to a CLOSE or OPEN state.

The fixed part 110 includes a fixed part support 111 constituting the outer shape of the fixed part 110, a fixed part arc contact 115 and a movable part arc contact 145b connected to the fixed part support 111, and the It consists of a fixed part gas outlet 113 through which arc gas generated when the arc contact 115 of the fixed part is separated is discharged.

The fixing part support 111 forms the outer shape of the fixing part 110, and the arc gas generated when the contacts 115 and 145b are separated flows into the inside and then passes through the fixing part gas outlet 113 to the outside. is emitted with

The fixed part arc contact 115 is provided inside the fixed part support 111 and is contacted or separated from the movable part arc contact 145b according to the movement of the movable part 140 so that the gas circuit breaker 100 is inserted. Or adjust so that it is blocked.

The fixed part gas outlet 113 is formed on the upper side of the fixed part arc contact 115 of the fixed part support 111, and when the fixed part arc contact 115 and the movable part arc contact 145b are separated The generated arc gas is discharged to the outside.

The movable part 140 moves away from the fixing part 110 when a fault current is applied, and adjusts the gas circuit breaker 100 to be cut off from the closed state.

At this time, the movable part 140 includes a movable part support 141, a cylinder 143 moving inside the movable part support 141, and a cylinder rod 145 connected to the cylinder 143 and moving together with the cylinder 143. ), a main nozzle 157 installed at the tip of the cylinder 143 and an auxiliary nozzle 159 installed at the center of the cylinder 143.

The movable part support 141 forms the outer shape of the movable part 140, and the cylinder 143 moves in the forward and backward directions inside.

At this time, the movable part gas outlet 155 is formed in the movable part support 141, and the high-temperature arc gas G1 generated when the movable part arc contact 145b and the fixed part arc contact 115 are separated is discharged from the movable part gas. It is discharged to the outside of the gas circuit breaker 100 through the outlet 155.

When a fault current is applied to the cylinder 143 and the gas circuit breaker 100 is adjusted to a shut-off state, the cylinder 143 moves in a direction away from the fixed part 110 inside the movable part support 141 .

At this time, the cylinder 143 is provided with a compression chamber 153 and an expansion chamber 151, and the movable part arc contact 145b and the fixed part arc contact 115 are separated to generate high-temperature arc gas (G1). Then, the arc gas passes through the expansion chamber 151 to become low-temperature arc gas G2 and then discharged toward the main nozzle 157 to extinguish the arc gas.

The cylinder rod 145 is connected to the cylinder 143 and moves together with the cylinder 143. The movable part arc contact 145b is provided inside one end of the cylinder rod 145, and the gas circuit breaker ( 100) is adjusted to the closed or shut-off state, the movable part arc contact 145b contacts or separates from the fixed part arc contact 115.

At this time, an arc gas discharge hole 145a is formed in the cylinder rod 145, and when the arc contact 145b of the movable part and the arc contact 115 of the fixed part are separated and high-temperature arc gas G1 is generated, the arc gas G1 is generated. The gas passes through the inside of the cylinder rod 145 and is discharged through the arc gas discharge hole 145a, and then is discharged to the outside of the gas circuit breaker 100 again through the moving part gas discharge port 155.

Meanwhile, a partition wall 147 is formed inside the movable part support 141 to be spaced apart from the compression chamber 153 toward the movable part 140.

The partition wall 147 is formed to be bent toward the cylinder rod 145 from the inside of the movable part support 141, and when the high-temperature arc gas G1 is discharged through the arc gas discharge hole 145a, the high-temperature Arc gas (G1) is prevented from flowing into the compression chamber (153).

More specifically, if the gas circuit breaker 100 is adjusted from the input state to the cut-off state, the arc contact point 115 of the fixed part and the arc contact point 145b of the movable part are separated and high-temperature arc gas G1 is generated. And, the high-temperature arc gas G1 passes through the cylinder rod 145 and is discharged into the movable part support 141 through the arc gas discharge hole 145a.

At this time, the high-temperature arc gas G1 discharged through the arc gas discharge hole 145a is discharged to the outside of the gas circuit breaker 100 again through the moving part gas outlet 155 .

However, in the conventional case, a part of the high-temperature arc gas G1 is discharged to the outside through the movable part gas outlet 155, and a part is introduced into the compression chamber 153 from the inside of the movable part support 141 and then It is introduced into the expansion chamber 151 again.

At this time, the high-temperature arc gas G1 introduced into the expansion chamber 151 is mixed with the low-temperature arc gas G2 in the expansion chamber 151 and then discharged toward the main nozzle 157, and each contact 115 , 145b) to extinguish the arc gas generated during the separation. In order to improve the extinguishing performance, the low-temperature arc gas (G2) must be discharged through the expansion chamber 151 to the contact points 115 and 145b, but the high-temperature Since the arc gas (G1) is mixed with the low-temperature arc gas (G2) of the expansion chamber 151, the temperature of the arc gas rises to a certain extent, and thus the arc extinguishing performance is remarkably deteriorated.

Therefore, the present invention provides the partition wall 147 to be spaced apart from the compression chamber 153, and the arc gas discharged through the arc gas discharge hole 145a passes through the partition wall 147 to the compression chamber 153. ), so that only the low-temperature arc gas (G2) of the expansion chamber 151 is discharged to the contact points 115 and 145b, the arc extinguishing performance through the arc gas is improved.

In addition, when the gas circuit breaker 100 is adjusted from the input state to the cutoff state, a certain stroke is applied so that the cylinder 143 moves in a direction away from the fixing part 110, and the arc gas When flowing into the compression chamber 153 through the gas discharge hole 145a, the cylinder 143 receives a constant force in the direction opposite to the moving direction due to the gas pressure of the arc gas flowing into the compression chamber 153. do.

Therefore, the stroke applied to move the cylinder 143 so that the gas circuit breaker 100 is in a shut-off state is changed, which causes an error in the shut-off operation of the gas circuit breaker 100.

However, since the present invention prevents the arc gas from flowing into the compression chamber 153 through the partition wall 147, the cylinder 143 moving toward the compression chamber 153 during a blocking operation prevents the arc gas from flowing into the compression chamber 153. Through this, it is not pressurized in the opposite direction to the moving direction, so that the breaking performance of the circuit breaker 100 is prevented from deteriorating through arc gas.

Meanwhile, a support 149 is formed at one end of the partition wall 147 on the side of the cylinder rod 145 so as to be bent toward the movable part 140.

Since the support 149 is positioned adjacent to the outer circumferential surface of the cylinder rod 145, it supports the movement of the cylinder rod 145 while preventing shaking during movement of the cylinder rod 145.

In addition, an opening 163 is formed between the partition wall 147 of the movable part support 141 and the compression chamber 153 so that external low-temperature arc gas G3 flows into the compression chamber 153. .

Therefore, the high-temperature arc gas (G1) discharged to the outside of the gas circuit breaker 100 through the movable part gas outlet 155 is lowered in temperature and introduced through the opening 163 (G3), and then the compression As it is introduced into the expansion chamber 151 through the chamber 153, it is combined with the low-temperature arc gas (G2) filled in the expansion chamber 151 and sprayed to the respective contacts 115 and 145b, so that the arc extinguishing performance is greatly improved. .

Meanwhile, as shown in FIGS. 5 and 6 , a guide part 161 for guiding external arc gas to flow into the compression chamber 153 is provided on one surface of the partition wall 147 on the compression chamber 153 side. more can be formed.

The guide part 161 is formed in a round shape, and when the low-temperature arc gas G3 outside the gas circuit breaker 100 flows into the compression chamber 153 through the opening part 163, it is an inflow path. guides the arc gas to smoothly flow into the compression chamber 153.

In addition, in the guide part 161, when the gas circuit breaker 100 is in the input state, one end P2 of the guide part 161 is higher than one end P2 of the arc gas discharge hole 145a in the compression chamber. It is formed to be located adjacent to (153).

Therefore, even if a part of the arc gas is discharged through the arc gas discharge hole 145a when the gas circuit breaker 100 starts to be adjusted from the cut-off state to the input state, it is blocked by the guide part 161 and the partition wall 147 and the It is prevented from being discharged between the compression chambers 153.

In the case of the present invention configured and operated as described above, a partition wall 147 formed to be bent toward the cylinder rod 145 is installed inside the movable part support 141, and the arc gas discharge hole 145a of the cylinder rod 145 By preventing the arc gas discharged through the partition wall 147 from entering the compression chamber 153 and the expansion chamber 151, the low-temperature arc gas G2 filled inside the expansion chamber 151 is It is mixed with arc gas (G1) to prevent deterioration of arc extinguishing performance due to temperature rise.

In addition, an opening 163 is formed in the movable part support 141 to be located between the partition wall 147 and the compression chamber 153, and the low-temperature arc gas G3 is passed through the opening 163 into the compression chamber. By introducing it into the expansion chamber 151 through the passage 153, the amount of low-temperature arc gas G2 in the expansion chamber 151 is increased, thereby improving the arc extinguishing performance of the gas circuit breaker 100.

In addition, by forming a support 149 at one end of the partition wall 147 so as to be bent toward the movable part 140, when the cylinder rod 145 moves toward the fixed part 110 or in the opposite direction, shaking during movement is prevented.

In addition, by forming a round guide part 161 on one surface of the partition wall 147, the low-temperature arc gas G2 outside the gas circuit breaker 100 smoothly flows into the compression chamber 153 through the guide part 161. do.

In addition, one end of the guide part 161 is located closer to the compression chamber 153 than the arc gas discharge hole 145a, so that the gas circuit breaker 100 is switched from the input state to the cut off state. In the initial state, the arc gas discharge hole Even if arc gas is discharged through 145a, arc gas is prevented from being discharged between the partition wall 147 and the compression chamber 153 through the guide part 161.

Although a preferred embodiment of the present invention has been described above, it is clear that the present invention can use various changes, modifications, and equivalents, and can be equally applied by appropriately modifying the above embodiment. Accordingly, the above description is not intended to limit the scope of the present invention, which is defined by the limits of the following claims.

10, 100: gas circuit breaker 20, 110: fixed part
21, 115: fixed part arc contact 40, 140: moving part
41, 143: cylinder 43, 145: cylinder rod
43a, 145a: arc gas discharge hole 43b, 145b: moving part arc contact
45, 153: compression chamber 47, 151: expansion chamber
49, 155: moving part gas outlet 111: fixed part support
113: fixed part gas outlet 141: movable part support
147: bulkhead 149: support
157: main nozzle 159: auxiliary nozzle
G1: high temperature arc gas G2: low temperature arc gas
161 guide part 163 opening part
P1: One end of the arc gas discharge hole P2: One end of the guide part

Claims (7)

A fixing part support forming a fixing part; a movable part support forming a movable part spaced apart from the fixed part; a fixed part arc contact formed on the fixed part support; a cylinder movably installed on the movable part support and provided with a compression chamber; a cylinder rod that moves according to the movement of the cylinder; a movable part arc contact formed on the cylinder rod to contact or separate from the fixed part arc contact; In the gas circuit breaker for a gas insulated switchgear formed in the cylinder rod and including an arc gas discharge hole through which arc gas is discharged,
A partition wall is formed inside the movable part support connected to the fixed part support to prevent the arc gas discharged through the arc gas discharge hole from flowing into the compression chamber by being spaced apart from the compression chamber.
A movable part gas outlet is formed in the movable part support,
The gas circuit breaker for the gas insulated switchgear, characterized in that the arc gas is discharged to the outside through the gas outlet of the moving part. According to claim 1,
The partition wall is a gas circuit breaker for a gas insulated switchgear, characterized in that formed to be bent toward the cylinder rod side from the movable part support. According to claim 2,
A gas circuit breaker for a gas insulated switchgear, characterized in that an opening is formed between the partition wall and the compression chamber of the movable part support so that an external arc gas flows into the compression chamber. According to claim 2 or 3,
A gas circuit breaker for a gas insulated switchgear, characterized in that a support for supporting the movement of the cylinder rod is formed on one surface of the partition wall on the side of the cylinder rod to be bent toward the movable part According to claim 2 or 3,
A gas circuit breaker for a gas insulated switchgear, characterized in that a guide portion for guiding an external arc gas to flow into the compression chamber is formed on one surface of the partition wall on the compression chamber side. According to claim 5,
Gas circuit breaker for gas insulated switchgear, characterized in that the guide portion is formed round. According to claim 6,
Gas circuit breaker for gas insulated switchgear, characterized in that when the gas circuit breaker is input state, one end of the compression chamber side of the guide is located closer to the compression chamber than the arc gas discharge hole.

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