JP2018098128A - Gas insulated switchgear - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a gas insulated switchgear capable of easily attaining a blocking duty required for a high-voltage switchgear by removing hot gas and improving insulation performance.SOLUTION: A compression chamber 30 is formed in a portion surrounded by a movable contact 21 and a movable shield 23. In the compression chamber 30, insulation gas in the inside is compressed by penetration of the movable contact 21 during opening operation. The insulation gas compressed in the compression chamber 30 flows to a space between a fixed contact 11 and the movable contact 21 from the compression chamber 30. Further, a suction chamber 31 is formed in a portion surrounded by the movable contact 21, a piston 25a of an operation rod 25 and the movable shield 23. The suction chamber 31 sucks hot gas by an electric-arc 40.SELECTED DRAWING: Figure 1

Description

  Embodiments described herein relate generally to a gas insulated switchgear having improved insulation characteristics.

  The high-voltage switchgear is a device that is responsible for interrupting the fault current in the power system. Such a switchgear is required to reliably cut off a small current to a large current. In particular, regarding the interruption of a large current, the following two interruption duties must be satisfied. Of the two interrupting duties, one is an obligation to interrupt the near line fault (SLF) current, and the other is an obligation to interrupt the breaker terminal short circuit fault (BTF) current.

  In a short-distance line failure (SLF), a voltage with a triangular waveform appears in the initial rise of the voltage immediately after the current zero (transient recovery voltage), although its absolute value is low but the rate of change is steep. Therefore, it may be difficult to cut off even though the short-circuit current is small. On the other hand, in the circuit breaker terminal short-circuit fault (BTF), the initial rise of the transient recovery voltage is gentle, but at the end, a voltage having a high absolute value is applied. This is because when a fault such as a ground fault or a short circuit occurs near the load-side power transmission line connected to the power-side circuit breaker, if the failure current is interrupted by the power-side circuit breaker, the current from all power sources Because it passes through.

  Therefore, in recent years, a gas-insulated switchgear in which a shut-off unit specialized for each of the two shut-off duties is connected to a pressure vessel sealed with SF6 gas as an insulating gas has been proposed. For example, by separating the internal space of the pressure vessel, one side contains a puffer type blocking part with excellent BTF blocking performance, and the other side contains a puffer type blocking part with excellent SLF blocking performance. Are electrically connected in series. According to this gas-insulated switchgear, the two shut-off parts share the shut-off duties that each of them is good at, so that two kinds of shut-off duties can be satisfied with certainty.

Japanese Patent Laid-Open No. 2015-43656

  In the gas insulated switchgear that shares the responsibility of interruption, one interruption part is a vacuum interruption part whose main role is interruption of accident current, and another interruption part is a gas contact part whose main role is insulation after interruption Sometimes. In this case, when the vacuum interrupter tries to extinguish the fault current, until the fault current is extinguished, not only the vacuum interrupter but also the gas contact part is connected with the stationary contact and the movable contact. An arc will occur between them.

  Since the gas contact portion plays a major role in insulation after interruption, the gas contact portion does not have a structure in which gas is blown against an arc generated between both contacts. Therefore, the insulating gas becomes a hot gas due to the arc, and this hot gas may stay in the vicinity of both contactors for a long time. As a result, the hot gas has caused the insulation performance between the two contacts to deteriorate. In particular, if the amount of hot gas remaining between the two contacts is large, there is a possibility of re-ignition, which may result in unsuccessful interruption.

  The present embodiment has been proposed to solve the above-described problem, and can improve the insulation performance by removing the hot gas, and can easily achieve the interrupting duty required for the high-voltage switch. An object is to provide a gas insulated switchgear.

  In order to achieve the above object, an embodiment of the present invention includes a pressure vessel in which an insulating gas is sealed, a stationary contact fixed inside the pressure vessel, and an opposing arrangement in the longitudinal direction of the stationary contact. A movable contact, a movable contact base fixed to the pressure vessel, a movable shield fixed to the movable contact base and arranged to surround the movable contact, and connected to the movable contact A gas-insulated switchgear comprising: a movable operation rod having a piston fixed thereto; and an operation mechanism for reciprocating the operation rod to bring the movable contact into and out of contact with the fixed contact. Elements (1) to (3) are provided.

(1) A compression chamber which is formed in a portion surrounded by the movable contact and the movable shield and in which the insulating gas is compressed when the movable contact enters during the opening operation.
(2) An insulating gas flow path for flowing the insulating gas compressed in the compression chamber from the compression chamber to a space between the fixed contact and the movable contact.
(3) A suction chamber that is formed in a portion surrounded by the movable contact, the piston, and the movable shield and sucks in hot gas heated by an arc generated between the fixed contact and the movable contact.

In addition, the embodiment of the present invention includes one provided with the following components (a) to (c).
(A) A compression chamber that is formed in a portion surrounded by the movable shield, the piston, and the movable contactor base and in which the insulating gas is compressed when the piston moves during the opening operation.
(B) An insulating gas flow path for flowing the insulating gas compressed in the compression chamber from the compression chamber to a space between the fixed contact and the movable contact.
(C) A suction chamber that is formed in a portion surrounded by the movable shield, the movable contact and the piston, and sucks in hot gas heated by an arc generated between the fixed contact and the movable contact.

Sectional drawing which shows the closed circuit state of the gas insulated switchgear which concerns on 1st Embodiment. Sectional drawing which shows the open circuit state of the gas insulated switchgear which concerns on 1st Embodiment. The principal part sectional view of a 1st embodiment. The principal part sectional view of a 1st embodiment. Sectional drawing which shows the closed circuit state of the gas insulated switchgear concerning 2nd Embodiment. Sectional drawing which shows the open circuit state of the gas insulated switchgear which concerns on 2nd Embodiment. Sectional drawing which shows the closed circuit state of the gas insulated switchgear which concerns on 3rd Embodiment. Sectional drawing which shows the open circuit state of the gas insulated switchgear which concerns on 3rd Embodiment. Sectional drawing which shows the closed circuit state of the gas insulated switchgear which concerns on 4th Embodiment. Sectional drawing which shows the open circuit state of the gas insulated switchgear which concerns on 4th Embodiment.

  Hereinafter, embodiments of a gas insulated switchgear according to the present invention will be described with reference to the drawings. In any of the gas-insulated switchgears according to the following embodiments, a plurality of shut-off portions that can share the shut-off duty are electrically connected in series, and are applied to the gas contact portions.

[First Embodiment]
(Constitution)
The first embodiment will be described with reference to FIGS. FIG. 1 is a cross-sectional view showing a closed state according to the first embodiment, and FIG. 2 is a cross-sectional view showing an open state according to the first embodiment. 3 and 4 are cross-sectional views of the main part of the first embodiment. As shown in FIGS. 1 and 2, the gas insulated switchgear 1 is provided with a pressure vessel 2 in which an insulating gas is sealed. Inside the pressure vessel 2, a fixed contact portion 10 and a movable contact portion 20 are arranged to face each other.

(Fixed contact part)
The fixed contact portion 10 includes a fixed contact 11, a fixed contact base 12, and a fixed shield 13. The fixed contact 11 is fixed to the fixed contact base 12 and / or the fixed shield 13. The fixed contact base 12 is fixed to the pressure vessel 2. The fixed shield 13 is installed on the end surface of the fixed contact base 12 so as to surround the periphery of the fixed contact 11. An arc resistant metal 14 having arc resistance is provided at the tip of the fixed contact 11.

(Movable contact part)
A movable shaft 3 extends from the movable contact portion 20 toward the outside of the pressure vessel 2, and an operation mechanism 5 is connected to the movable shaft 3. The operation mechanism 5 is attached to the pressure vessel 2. The operation mechanism 5 is a mechanism that linearly reciprocates the operation rod 25 via the movable shaft 3 and separates the movable contact 21 from the fixed contact 11.

  The movable contact portion 20 includes a movable contact 21, a movable contact base 22, a movable shield 23, an arc-resistant metal 24, an operating rod 25, and a current collecting contact 26. Among these, the movable contact 21 is disposed so as to be movable in the longitudinal direction of the fixed contact 11. FIG. 3 shows a cross-sectional view of the movable contact 21.

  As shown in FIG. 3, the movable contact 21 has a hollow portion 21a, and two cylindrical portions having different outer diameters are integrally formed. Of the two cylindrical portions having different outer diameters, the thick cylindrical portion 21c having a large outer diameter is a round can shape, and the thin cylindrical portion 21d having a small outer diameter is a pipe shape. For this reason, the shape of the hollow portion 21a has a T-shaped cross section.

  The thick cylindrical portion 21 c of the movable contact 21 is a portion that comes into contact with the fixed contact 11. In the thick cylindrical portion 21c, an arc-resistant metal 24 is attached to the end surface near the fixed contact 11. The arc-resistant metal 24 is provided over the entire end surface of the thick cylindrical portion 21c. A plurality of vent holes 24 a communicating with the hollow portion 21 a of the movable contact 21 are formed in the arc resistant metal 24. On the other hand, the operation rod 25 is fixed to the thin cylindrical portion 21d. In the narrow cylinder portion 21d, a hot gas suction hole 21b communicating with the hollow portion 21a is formed at an end portion near the operation rod 25. The hot gas suction hole 21b is opened in the circumferential portion of the thin cylindrical portion 21d.

  One end of the operating rod 25 is connected to the movable shaft 3, and the other end is fixed to the end of the narrow cylindrical portion 21 d of the movable contact 21. In the operation rod 25, a piston 25a is attached to the end of the movable contact 21 on the side to which the thin cylindrical portion 21d is fixed. The piston 25 a is provided such that its outer peripheral portion slides on the inner peripheral portion of the movable shield 23.

  The movable contact base 22 is fixed to the pressure vessel 2. A current collecting contact 26 is disposed at the tip of the movable contact base 22 so as to be in contact with the outer periphery of the operation rod 25. The movable shield 23 is fixed to the end surface of the movable contact base 22 and is disposed so as to surround the movable contact 21.

  As shown in FIG. 4, the movable shield 23 has a hollow portion formed therein, and a partition wall 23b is provided near the middle thereof. An opening 23a is formed in the center of the partition wall 23b. A thin cylindrical portion 21d of the movable contact 21 is slidably inserted into the opening 23a (shown in FIGS. 1 and 2).

  The movable shield 23 divides the internal space of the movable shield 23 into a space on the fixed contact 11 side and a space on the movable contact base 22 side by the partition wall 23b. The space on the fixed contact 11 side is the compression chamber 30, and the space on the movable contact base 22 side is the suction chamber 31. As described above, the compression shield 30 is formed in the movable shield 23 near the fixed contact 11, and the suction chamber 31 is formed on the opposite side of the compression chamber 30 across the partition wall 23 b. The compression chamber 30 and the compression chamber 30 have the same inner diameter.

(Compression chamber)
Of the two spaces formed in the movable shield 23, the compression chamber 30 is a space surrounded by the outer peripheral portion of the thick cylindrical portion 21 of the movable contact 21 and the inner peripheral portion of the movable shield 23. In the compression chamber 30, during the opening operation, the thick cylindrical portion 21c of the movable contactor 21 that moves moves linearly enters the movable shield 23 with a predetermined gap 30a (shown in FIG. 2), and enters the thick cylindrical portion 21c. Thus, the insulating gas inside the compression chamber 30 is compressed.

(Insulating gas flow path)
The gap 30 a in the compression chamber 30 is formed by making the outer peripheral portion of the thick cylindrical portion 21 c slightly smaller than the inner peripheral portion of the movable shield 23. The gap 30 a becomes an insulating gas flow path for flowing the insulating gas in the compression chamber 30 toward the space between the fixed contact 11 and the movable contact 21. That is, in the first embodiment, the insulating gas compressed in the compression chamber 30 is jetted into the space between the fixed contact 11 and the movable contact 21 through the gap 30a that is an insulating gas flow path. It will be.

(Suction room)
As shown in FIG. 2, when the movable contact 21 is separated from the fixed contact 11, an arc 40 is generated between both the contacts 11 and 21. The surrounding insulating gas is heated by the arc 40, and the insulating gas becomes a hot gas. A space for sucking such hot gas is the suction chamber 31. The suction chamber 31 is a space surrounded by the outer peripheral portion of the movable contact 21, the outer peripheral portion of the piston 25 a of the operating rod 25, and the inner peripheral portion of the movable shield 23.

  In the closed state shown in FIG. 1, the hot gas suction hole 21 b formed in the narrow cylindrical portion 21 d of the movable contact 21 is located in the partition wall 23 b of the movable shield 23, and sucks the hollow portion 21 a of the movable contact 21. The chamber 31 is not in communication. However, in the open circuit state, the movable contactor 21 moves to the suction chamber 31 side as the movable contactor 21 moves. Therefore, in the open circuit state, the hot gas suction hole 21 b communicates with the hollow portion 21 a of the movable contact 21 and the suction chamber 31.

(Opening operation)
The opening operation of the gas insulated switchgear 1 according to the first embodiment configured as described above will be described from the closed state shown in FIG. 1 to the open state shown in FIG. First, in the closed state shown in FIG. 1, when the operating mechanism 5 is started by an opening command sent from the outside, the movable shaft 3 is driven to the right side of FIG. Accordingly, the operating rod 25 and the movable contact 21 are similarly driven to the right side, and the movable contact 21 is separated from the fixed contact 11. When the movable contact 21 is separated from the fixed contact 11, an arc 40 is generated between the movable contact 21 and the fixed contact 11 (shown in FIG. 2).

  When the opening operation proceeds, the thick cylindrical portion 21c of the movable contact 21 enters the compression chamber 30 as shown in FIG. Therefore, the thick cylinder portion 21 c compresses the insulating gas inside the compression chamber 30. The compressed insulating gas is ejected into the space where the arc 40 is generated through the gap 30a between the thick cylindrical portion 21c of the movable contact 21 and the movable shield 23.

  Further, the insulating gas heated by the arc 40 becomes a hot gas, and the hot gas enters the hollow portion 21 a of the movable contact 21 through the vent hole 24 a of the arc-resistant metal 24. As the opening operation proceeds, the piston 25a of the operating rod 25 is driven to the right, so that the space of the suction chamber 31 is expanded and the pressure of the insulating gas inside the suction chamber 31 is lower than the surroundings.

  At this time, since the thin cylindrical portion 21d of the movable contact 21 has moved to the right in the drawing, the hot gas suction hole 21b of the movable contact 21 is positioned on the suction chamber 31 side (state of FIG. 2). ). Therefore, the hollow portion 21a of the movable contact 21 and the suction chamber 31 communicate with each other by the hot gas suction 21b.

  As a result, the hot gas that has entered the hollow portion 21 a of the movable contact 21 from the vent hole 24 a of the arc-resistant metal 24 passes through the hot gas suction hole 21 b and flows into the suction chamber 31. Thus, the hot gas flows into the suction chamber 31 through the hollow portion 21a of the movable contact 21 and the hot gas suction hole 21b without staying in the space where the arc 40 is generated.

  When the opening operation further proceeds, the fault current is interrupted by an external interrupting unit connected in series to the gas insulated switchgear 1. Therefore, the arc 40 generated between the fixed contact 11 and the movable contact 21 disappears. However, even if the arc 40 is extinguished, the hot gas heated by the arc 40 still remains in the space between the fixed contact 11 and the movable contact 21 and is insulative performance against the recovery voltage after interruption. Is in a lowered state.

  In the first embodiment, as described above, the insulating gas compressed in the compression chamber 30 is ejected from the gap 30a to diffuse and cool the hot gas. In the first embodiment, the hot gas is sucked into the suction chamber 31 through the plurality of vent holes 24 a, the hollow portion 21 a of the movable contact 21 and the hot gas suction hole 21 b. The opening operation is completed when the state shown in FIG. 2 is reached, and the movable contact 21 is completely accommodated in the compression chamber 30 inside the movable shield 23.

(Action and effect)
As described above, in the first embodiment, the thick cylindrical portion 21c of the movable contactor 21 enters during the opening operation so that the insulating gas inside is compressed and the space where the arc 40 is generated. On the other hand, a gap 30 a for flowing the insulating gas in the compression chamber 30 and a suction chamber 31 for sucking in hot gas by the arc 40 are provided.

  In the first embodiment described above, the hot gas can be diffused and cooled by blowing the insulating gas compressed in the compression chamber 30 from the gap 30a against the hot gas by the arc 40. Further, the hot gas heated by the arc 40 can be sucked into the suction chamber 31. For this reason, it is possible to reliably remove the hot gas staying between the stationary contact 11 and the movable contact 21 from the space where the arc 40 is generated.

  According to the first embodiment as described above, there is no fear that the fixed contact 11 and the movable contact 21 are re-ignited, and a good insulation performance can be obtained with respect to the recovery voltage after the interruption. Thereby, in the gas insulated switchgear 1, it becomes possible to easily achieve the interrupting duty required for the high voltage switch.

  In the first embodiment, the gap 30 a formed along the outer periphery of the movable contact 21 is an insulating gas flow path through which the insulating gas compressed in the compression chamber 30 flows. Therefore, the insulating gas that has passed through the gap 30a is intensively blown toward the tip of the fixed contact 11 from the outside to the arc 40, and the hot gas from the arc 40 can be efficiently blown away. it can.

  Moreover, if the thick cylindrical portion 21c of the movable contactor 21 enters the inside of the compression chamber 30 even a little, the thick cylindrical portion 21c compresses the insulating gas inside the compression chamber 30, so that the gap 30a that is an insulating gas flow path is The insulating gas is blown toward the space where the arc 40 is generated from the initial stage of the opening operation. Therefore, the hot gas can be diffused and cooled quickly, which can contribute to the improvement of the insulation performance.

  Further, in the movable contact 21 in the first embodiment, the hollow portion 21a and the hot gas suction hole 21b are formed, and the vent hole of the arc-resistant metal 24 for sucking the hot gas is formed on the end surface near the fixed contact 11. 24a is formed. Here, since the arc-resistant metal 24 is provided over the entire end surface of the thick cylindrical portion 21 c, the entire surface covers the space where the arc 40 is generated. Therefore, the movable contact 21 can suck a large amount of hot gas through the vent hole 24a, and can quickly remove the hot gas from the space where the arc 40 is generated.

  Moreover, in the first embodiment, the compression chamber 30 and the suction chamber 31 are continuously formed in the movable shield 23, and the insulating gas is compressed by the entry of the thick cylindrical portion 21c into the compression chamber 30, and at the same time, the hollow portion 21a and Hot gas is sucked into the suction chamber 31 through the hot gas suction hole 21b. According to such a first embodiment, the movable contact 21 sliding inside the movable shield 23 can contribute to both compression of insulating gas and suction of hot gas, and the configuration is simplified. It is possible to demonstrate excellent insulation performance while proceeding with the process.

[Second Embodiment]
(Constitution)
Next, a second embodiment of the gas insulated switchgear according to the present invention will be described with reference to FIGS. FIG. 5 is a cross-sectional view showing a closed state of the gas insulated switchgear according to the second embodiment. FIG. 6 is a sectional view showing an open circuit state of the gas insulated switchgear according to the second embodiment. In addition, the same code | symbol is attached | subjected to the part which is the same as that of 1st Embodiment, or similar, and the overlapping description is abbreviate | omitted.

  In the second embodiment, the configuration of the insulating gas channel is modified. In the second embodiment, a sliding packing 27 is installed in the gap 30a between the outer peripheral portion of the thick cylindrical portion 21c of the movable contact 21 shown in FIGS. 1 and 2 and the compression chamber 30 on the movable shield 23 side. Yes. Therefore, the gap 30a does not become an insulating gas flow path through which the insulating gas compressed in the compression chamber 30 flows.

  In the second embodiment, the movable contact 21 is formed with a through hole 28 extending in the longitudinal direction. The through hole 28 communicates with the compression chamber 30 and communicates with several of the vent holes 24 a of the arc-resistant metal 24. In the second embodiment, a space including the through hole 28 and the vent hole 24a of the arc-resistant metal 24 communicated therewith becomes an insulating gas flow path. Of the plurality of vent holes 24a, those that are not communicated with the through-hole 21b are communicated with the hollow portion 21a of the movable contact 21 and are included in the flow path for sucking in hot gas.

(Opening operation)
The opening operation of the gas insulated switchgear 1 according to the second embodiment configured as described above will be described from the closed state shown in FIG. 5 to the open state shown in FIG. In the closed state shown in FIG. 5, the first operation is performed until the operating mechanism 5 is started by an opening command sent from the outside, the movable contact 21 is separated from the fixed contact 11, and the arc 40 is generated. It is the same as the form.

  When the opening operation proceeds, the thick cylindrical portion 21c of the movable contactor 21 enters the compression chamber 30 as shown in FIG. Therefore, the thick cylinder portion 21 c compresses the insulating gas inside the compression chamber 30. The compressed insulating gas is ejected through the through hole 28 and the vent hole 24a into the space where the arc 40 is generated.

  Since the operation until the hot gas heated by the arc 40 is sucked into the suction chamber 31 is the same as that in the first embodiment, it is omitted here. In the closed state of FIG. 5, the piston 25 a of the operating rod 25 is in contact with the partition wall 23 b of the movable shield 23, and the suction chamber 31 has almost no volume.

(Action and effect)
In the second embodiment, as in the first embodiment, the hot gas generated by the arc 40 can be diffused and cooled by the insulating gas ejected from the compression chamber 30 and sucked into the suction chamber 31. For this reason, the hot gas staying between the stationary contact 11 and the movable contact 21 can be surely removed to improve the insulation performance, and the interruption duty required for the high voltage switch can be easily achieved. Is possible.

  In the second embodiment, the through hole 21 b provided in the movable contact 21 is an insulating gas flow path through which the insulating gas compressed in the compression chamber 30 flows. Therefore, the insulating gas that has passed through the through hole 21b is blown against the arc 40 so as to spread from the inside to the outside, and the hot gas from the arc 40 is blown in the circumferential direction of the movable contact 21. Can be scattered.

  Further, in the second embodiment, a sliding packing 27 is installed between the outer peripheral portion of the movable contact 21 and the inner peripheral portion of the movable shield 23, and the movable contact 21 penetrates as an insulating gas flow path. Hole 21b is formed. Therefore, by appropriately selecting the number and diameter of the through holes 28 formed in the movable contact 21, it is possible to easily adjust the gas amount of the insulating gas ejected toward the space where the arc 40 is generated. Thereby, it is possible to efficiently diffuse and cool the hot gas by the arc 40.

[Third Embodiment]
(Constitution)
Next, a third embodiment of the gas insulated switchgear according to the present invention will be described with reference to FIGS. FIG. 7 is a cross-sectional view showing a closed state of the gas insulated switchgear according to the third embodiment. FIG. 8 is a cross-sectional view showing an open circuit state of the gas insulated switchgear according to the third embodiment. In addition, the same code | symbol is attached | subjected to the part which is the same as that of 1st Embodiment, or similar, and the overlapping description is abbreviate | omitted.

  In the third embodiment, the arrangement of the compression chamber and the suction chamber is modified. In the first and second embodiments, the compression chamber 30 is disposed near the stationary contact 11, and the suction chamber 31 is disposed near the operation mechanism 5 when viewed from the compression chamber 30. In contrast, in the third embodiment, the suction chamber 31A is disposed near the stationary contact 11, and the compression chamber 30A is disposed near the operation mechanism 5 when viewed from the suction chamber 31A. The compression chamber 30 </ b> A and the suction chamber 31 </ b> A are spaces in which the space provided in the inner peripheral portion of the movable shield 23 is divided by the piston 25 a of the operation rod 25.

(Compression chamber and insulating gas flow path)
In the third embodiment, a space surrounded by the inner peripheral portion of the movable shield 23, the piston 25a of the operation rod 25, and the inner peripheral portion of the movable contact base 22 is defined as a compression chamber 30A. The movable contact base 22 has an intake hole 22b.

  The intake hole 22b communicates the internal space 22a of the pressure vessel 2 and the compression chamber 30A. A groove 32a is provided adjacent to the intake hole 22b, and a ring plate-like valve 32 is attached to the groove 32a. The valve 32 has a structure that closes the intake hole 22a due to a pressure difference when the pressure in the compression chamber 30A becomes higher than the pressure in the internal space 22a of the pressure vessel 2.

  In such a compression chamber 30A, the internal insulating gas is compressed by moving the piston 25a of the operating rod 25 during the opening operation. An insulating gas blowing hole 25 b is formed at the end of the operation rod 25. The insulating gas blowing hole 25b allows the hollow portion 21a of the movable contactor 21 and the compression chamber 30A to communicate with each other. In the third embodiment, a space including the insulating gas blowing hole 25b of the operating rod 25, the hollow portion 21a of the movable contactor 21, and the vent hole 24a of the arc-resistant metal 24 serves as an insulating gas flow path.

(Suction chamber and hot gas flow path)
In the third embodiment, the space surrounded by the inner peripheral portion of the movable shield 23, the outer peripheral portion of the movable contact 21 and the piston 25a is defined as a suction chamber 31A for sucking hot gas heated by the arc 40.

  In the movable shield 23, an accommodation chamber 33 capable of accommodating the thick cylindrical portion 21c of the movable contact 21 is formed near the fixed contact 11, and a suction chamber 31A is provided on the opposite side of the accommodation chamber 33 across the partition wall 23b. Is formed. In the partition wall 23b, a hot gas suction hole 23c is formed around the opening 23a, and the storage chamber 33 and the suction chamber 31A are always in communication with each other by the hot gas suction hole 23c. The inner diameter of the suction chamber 31 </ b> A is larger than the inner diameter of the storage chamber 33.

  In the accommodation chamber 33, a gap 33 a is provided between the outer peripheral portion of the thick cylindrical portion 21 c of the movable contact 21 and the inner peripheral portion of the movable shield 23. The gap 33 a is formed by making the outer peripheral portion of the thick cylindrical portion 21 c slightly smaller than the inner peripheral portion of the movable shield 23. The gap 33a serves as a hot gas flow path for flowing the hot gas heated by the arc 40 toward the suction chamber 31A. Accordingly, in the third embodiment, the hollow portion 21a of the movable contact 21 does not serve as a hot gas flow path, and unlike the first embodiment, the suction is drawn into the end of the movable contact 21. The hot gas suction hole 21b for communicating with the chamber 31 is not formed.

(Opening operation)
In the gas insulated switchgear 1 according to the third embodiment configured as described above, the opening operation from the closed state shown in FIG. 7 to the open state shown in FIG. 8 will be described. First, in the closed state shown in FIG. 7, the operating mechanism 5 is started by an opening command sent from the outside, and the movable shaft 3 is driven to the right side in the figure. Therefore, the operating rod 25 and the movable contact 21 are similarly driven to the right side, and the movable contact 21 is separated from the fixed contact 11. When the movable contact 21 is separated from the fixed contact 11, an arc 40 is generated between the movable contact 21 and the fixed contact 11 (shown in FIG. 8).

  When the opening operation proceeds, as shown in FIG. 8, the thick cylindrical portion 21c of the movable contactor 21 enters the inside of the accommodation chamber 33, and the piston 25a is driven to the right side in the drawing. Therefore, the pressure of the insulating gas inside the suction chamber 31 is lower than the surroundings. As a result, the hot gas from the arc 40 passes through the housing chamber 33 from the gap 33 a, passes through the hot gas suction hole 23 c of the partition wall 23 b of the movable shield 23, and flows into the suction chamber 31.

  Further, since the piston 25a is driven to the right side in the drawing, the insulating gas inside the compression chamber 30A is compressed by the piston 25a. The insulating gas compressed in the compression chamber 30A passes through the insulating gas blowing hole 25b of the operating rod 25, the hollow portion 21a of the movable contact 21 and the vent hole 24a of the arc-resistant metal 24 to the fixed contact 11 side. It is ejected.

  When the opening operation further proceeds, the fault current is interrupted by an external circuit breaker connected in series with the gas-insulated switchgear 1, so that the arc 40 generated between the fixed contact 11 and the movable contact 21 is It will disappear. At this time, in the conventional gas-insulated switchgear that does not have a structure such as blowing gas, even if the arc 40 disappears, the hot gas heated by the arc 40 still remains in the stationary contact 11 and the movable contact 21. The insulation performance is in a reduced state with respect to the recovery voltage after the interruption.

  However, in the third embodiment, as described above, the insulating gas compressed in the compression chamber 30A passes through the insulating gas blowing hole 25b and the hollow portion 21a and is blown out from the vent hole 24a, so that the hot gas is diffused. Can be cooled. In the third embodiment, the hot gas is sucked into the suction chamber 31A through the hot gas suction hole 23c, the accommodation chamber 33, and the gap 33a of the movable shield 23. The opening operation ends when the state shown in FIG. 8 is reached, and the movable contact 21 is completely accommodated in the accommodation chamber 33.

(Action and effect)
As described above, in the third embodiment, the compression chamber 30A in which the insulating gas inside is compressed by the movement of the piston 25a during the opening operation and the space in which the arc 40 is generated are contained in the compression chamber 30. An insulating gas flow path (insulating gas blowing hole 25b of the operating rod 25, a hollow portion 21a of the movable contact 21 and a vent hole 24a of the arc-resistant metal 24) through which the insulating gas flows, and a suction chamber 31A for sucking hot gas from the arc 40 It has.

  In the third embodiment described above, the hot gas can be diffused and cooled by blowing the insulating gas compressed in the compression chamber 30 </ b> A to the hot gas by the arc 40. Further, the hot gas heated by the arc 40 can be sucked into the suction chamber 31A. For this reason, it becomes possible to remove the hot gas staying between the stationary contact 11 and the movable contact 21 from the space where the arc 40 is generated.

  According to the third embodiment, as in the first embodiment, there is no fear that the fixed contact 11 and the movable contact 21 are re-ignited, and the insulation performance is good with respect to the recovery voltage after the interruption. Can be obtained. Thereby, in the gas insulated switchgear 1, it becomes possible to easily achieve the interrupting duty required for the high voltage switch.

  In 3rd Embodiment, since the clearance gap 33a of the storage chamber 33 formed along the outer peripheral part of the thick cylinder part 21c of the movable contact 21 is made into the flow path for inhaling a hot gas, from generation | occurrence | production space of the arc 40 Hot gas can be sucked in efficiently and intensively. In addition, when the thick cylindrical portion 21c of the movable contactor 21 enters the interior of the accommodation chamber 33 even a little, the insulating gas inside the accommodation chamber 33 can be pushed into the suction chamber 31A through the hot gas suction hole 23c. Therefore, since the piston 25a easily moves in the right direction in the figure, the insulating gas in the compression chamber 30A can be strongly compressed.

  In the third embodiment, the movable contact base 22 is formed with an intake hole 22b that communicates the internal space 22a of the pressure vessel 2 and the compression chamber 30A, and a valve 32 is attached to the intake hole 22b. When the pressure of 30A becomes higher than the pressure of the internal space 22a of the pressure vessel 2, the valve 32 closes the intake hole 22b due to the pressure difference. Therefore, the insulating gas in the compression chamber 30 </ b> A does not leak into the internal space 22 a of the pressure vessel 2, and vigorously flows from the insulating gas blowing hole 25 b of the operating rod 25 toward the hollow portion 21 a of the movable contact 21. Can be extruded.

  Furthermore, in 3rd Embodiment, the insulating gas flow path is comprised from the hollow part 21a of the movable contact 21, the insulating gas blowing hole 25b of the operation rod 25, and the vent hole 24a of the arc-resistant metal 24, and this Through the insulating gas flow path, the insulating gas compressed in the compression chamber 30 </ b> A flows toward the space where the arc 40 is generated. Here, since the arc-resistant metal 24 is provided over the entire end surface of the thick cylindrical portion 21 c, the entire surface faces the space where the arc 40 is generated. Therefore, a large amount of insulating gas can be blown from the vent hole 24a at once to the hot gas. As a result, the hot gas can be efficiently diffused and cooled.

  Further, the compression chamber 30A and the suction chamber 31A are spaces divided by the piston 25a, and by simply sliding the piston 25a in the movable shield 23, the compression of the insulating gas in the compression chamber 30A and the suction chamber 31A are performed. The hot gas can be sucked in. According to such 3rd Embodiment, it is possible to implement | achieve the outstanding insulation performance with a simple structure.

[Fourth Embodiment]
(Constitution)
Next, a fourth embodiment of the gas insulated switchgear according to the present invention will be described with reference to FIG. 9 and FIG. FIG. 9 is a cross-sectional view showing a closed state of the gas insulated switchgear according to the fourth embodiment. FIG. 10 is a cross-sectional view showing an open circuit state of the gas insulated switchgear according to the fourth embodiment. In addition, the same code | symbol is attached | subjected to the part which is the same as that of the form of 1st-3rd embodiment, or is similar, and the overlapping description is abbreviate | omitted.

  In the fourth embodiment, the hot gas flow path configuration is modified. In the fourth embodiment, the sliding packing 27 is installed in the gap 33a between the outer peripheral portion of the thick cylindrical portion 21c of the movable contact 21 shown in FIGS. 7 and 8 and the accommodating chamber 33 on the movable shield 23 side. Yes. Therefore, the gap 33a does not become a hot gas flow path by the arc 40.

  In the fourth embodiment, the movable contact 21 is formed with a through hole 28A extending in the longitudinal direction. The through hole 28A is provided so as to face the hot gas suction hole 23d formed in the partition wall 23b of the movable shield 23. The through hole 28 </ b> A communicates with the accommodation chamber 33 and also communicates with several of the vent holes 24 a of the arc-resistant metal 24.

  In the fourth embodiment, a space including the vent hole 24a of the arc-resistant metal 24, the through hole 28A, the vent hole 24a of the arc-resistant metal 24 communicated therewith, and the hot gas suction hole 23c of the movable shield 23 is provided. , A flow path for sucking hot gas into the suction chamber 31A. Of the plurality of vent holes 24a, those not communicating with the through hole 21b are communicated with the hollow portion 21a, and these are included in the insulating gas flow path for flowing the insulating gas compressed in the compression chamber 30A. It is. Moreover, since the hollow part 21a of the movable contact 21 does not become a hot gas flow path as in the third embodiment, the hot gas suction hole 21b is not formed in the movable contact 21.

(Opening operation)
The opening operation of the gas insulated switchgear 1 according to the fourth embodiment configured as described above will be described from the closed state shown in FIG. 9 to the open state shown in FIG. In the closed state shown in FIG. 9, the first operation is performed until the operating mechanism 5 is started by the opening command sent from the outside, the movable contact 21 is separated from the fixed contact 11, and the arc 40 is generated. It is the same as the form.

  When the opening operation proceeds, as shown in FIG. 10, the thick cylindrical portion 21c of the movable contactor 21 enters the inside of the housing chamber 33, and the piston 25a is driven to the right side of the drawing. Therefore, the pressure of the insulating gas inside the suction chamber 31 is lower than the surroundings. As a result, the hot gas from the arc 40 enters the through hole 28 </ b> A formed in the movable contact 21 from the vent hole 24 a of the arc-resistant metal 24, passes through the storage chamber 33, and the hot gas in the partition wall 23 b of the movable shield 23. The air passes through the suction hole 23 c and flows into the suction chamber 31.

  Further, since the piston 25a is driven to the right side in the drawing, the insulating gas inside the compression chamber 30A is compressed by the piston 25a. The insulating gas compressed in the compression chamber 30A passes through the insulating gas blowing hole 25b of the operating rod 25, the hollow portion 21a of the movable contact 21 and the vent hole 24a of the arc-resistant metal 24 to the fixed contact 11 side. It is ejected. The flow of such an insulating gas is the same as that in the third embodiment.

(Action and effect)
In the fourth embodiment, similarly to the third embodiment, the hot gas generated by the arc 40 can be diffused and cooled by the insulating gas ejected from the compression chamber 30A and sucked into the suction chamber 31A. For this reason, the hot gas staying between the stationary contact 11 and the movable contact 21 can be surely removed to improve the insulation performance, and the interruption duty required for the high voltage switch can be easily achieved. Is possible.

  Further, in the fourth embodiment, a sliding packing 27 is installed between the outer peripheral portion of the movable contact 21 and the inner peripheral portion of the movable shield 23, and a flow path for sucking hot gas into the movable contact 21 is provided. A through-hole 28A is formed. Therefore, the gas amount of the hot gas sucked from the space where the arc 40 is generated into the suction chamber 31A can be easily adjusted by appropriately selecting the number and diameter of the through holes 28A.

  Moreover, in the fourth embodiment, since the through hole 28A is provided so as to face the hot gas suction hole 23d of the movable shield 23, it is possible to smoothly flow the hot gas into the suction chamber 31A. Therefore, it is possible to efficiently remove the hot gas remaining between the fixed contact 11 and the movable contact 21.

[Other Embodiments]
Although several embodiments of the present invention have been described, these embodiments are presented by way of example and are not intended to limit the scope of the invention. These embodiments can be implemented in various other forms, and various omissions, replacements, and changes can be made without departing from the spirit of the invention. These embodiments and their modifications are included in the scope and gist of the invention, and are also included in the invention described in the claims and the equivalents thereof.

  For example, the size of the gaps 30a and 33a formed along the outer periphery of the movable contact 21, the shape and size of the movable contact 21, the number and shape of the through holes 28 and 28A formed in the movable contact 21, and compression The shapes and sizes of the chambers 30 and 30A and the suction chambers 31 and 31A can be selected as appropriate.

DESCRIPTION OF SYMBOLS 1 ... Gas insulation switchgear 2 ... Pressure vessel 3 ... Movable shaft 5 ... Operation mechanism 10 ... Fixed contact part 11 ... Fixed contact part 12 ... Fixed contact base 13 ... Fixed shield 20 ... Movable contact part 21 ... Movable Contact 21a ... Hollow portion 21b ... Hot gas suction hole 21c ... Thick tube portion 21d ... Narrow tube portion 22 ... Movable contactor base 22a ... Inside space 22b of pressure vessel ... Air intake hole 23 ... Moving shield 23a ... Opening portion 23b 23c ... Hot gas suction hole 24 ... Arc resistant metal 24a ... Vent hole 25 ... Operating rod 25a ... Piston 25b ... Insulating gas outlet hole 26 ... Current collector contact 27 ... Sliding packing 28, 28A ... Through hole 30, 30A ... Compression Chamber 31, 31A ... Suction chamber 32 ... Valve 32a ... Groove 33 ... Storage chamber 30a, 33a ... Gap 40 ... Arc

Claims (12)

A pressure vessel in which the insulating gas is sealed;
A stationary contact fixed inside the pressure vessel;
A movable contact disposed oppositely in the longitudinal direction of the fixed contact;
A movable contact base fixed to the pressure vessel;
A movable shield fixed to the movable contact base and arranged to surround the periphery of the movable contact;
A movable operating rod connected to the movable contact and fixed with a piston;
An operation mechanism for reciprocating the operation rod to separate the movable contact with the fixed contact;
In a gas insulated switchgear equipped with
A compression chamber that is formed in a portion surrounded by the movable contact and the movable shield and in which the insulating gas is compressed by entering the movable contact during the opening operation;
An insulating gas flow path for flowing the insulating gas compressed in the compression chamber from the compression chamber to a space between the fixed contact and the movable contact;
A suction chamber for sucking hot gas formed by an arc generated between the fixed contact and the movable contact formed in a portion surrounded by the movable contact, the piston and the movable shield;
Gas insulated switchgear with   The gas insulated switchgear according to claim 1, wherein a gap serving as the insulating gas flow path is provided between an outer peripheral portion of the movable contact and an inner peripheral portion of the movable shield. Between the outer peripheral portion of the movable contact and the inner peripheral portion of the movable shield, a sliding packing is installed,
The gas insulated switchgear according to claim 1, wherein the movable contact is formed with a through hole serving as the insulating gas flow path.   The gas-insulated switchgear according to any one of claims 1 to 3, wherein the movable contact is formed with a hollow portion and a hot gas suction hole for communicating the hollow portion with the suction chamber. In the movable shield, the compression chamber is formed near the fixed contact and the suction chamber is formed on the opposite side of the compression chamber across the partition wall,
The partition is provided with an opening,
The movable contact is formed of a member in which two cylindrical portions having different outer diameters are integrally formed. Of the two cylindrical portions having different outer diameters, the cylindrical portion having a larger diameter is replaced with the compression chamber. The gas-insulated switchgear according to any one of claims 1 to 4, wherein the gas-insulated switchgear is formed so as to be capable of being accommodated, and a cylindrical portion having a smaller diameter is slidably attached to the opening of the partition wall. A pressure vessel in which the insulating gas is sealed;
A stationary contact fixed inside the pressure vessel;
A movable contact disposed oppositely in the longitudinal direction of the fixed contact;
A movable contact base fixed to the pressure vessel;
A movable shield fixed to the movable contact base and arranged to surround the periphery of the movable contact;
A movable operating rod connected to the movable contact and fixed with a piston;
An operation mechanism for reciprocating the operation rod to separate the movable contact with the fixed contact;
In a gas insulated switchgear equipped with
A compression chamber that is formed in a portion surrounded by the movable shield, the piston, and the movable contact base and in which the insulating gas is compressed by moving the piston during the opening operation;
An insulating gas flow path for flowing the insulating gas compressed in the compression chamber from the compression chamber to a space between the fixed contact and the movable contact;
A suction chamber for sucking hot gas formed by an arc generated between the fixed contact and the movable contact formed in a portion surrounded by the movable shield, the movable contact and the piston;
Gas insulated switchgear with   The gas insulated switchgear according to claim 6, wherein a gap for sucking in the hot gas is provided between an outer peripheral portion of the movable contact and an inner peripheral portion of the movable shield. Between the outer peripheral portion of the movable contact and the inner peripheral portion of the movable shield, a sliding packing is installed,
The gas insulated switchgear according to claim 6, wherein a hot gas suction hole communicating with the suction chamber is formed in the movable contact. A hollow portion is formed in the movable contact,
The gas-insulated switchgear according to any one of claims 6 to 8, wherein an insulating gas blow-out hole for communicating the hollow portion and the compression chamber is formed in the operation rod. The movable shield forms a storage chamber capable of storing a part of the movable contact near the fixed contact and forms the suction chamber on the opposite side of the storage chamber with a partition wall interposed therebetween,
The partition wall is provided with a hot gas suction hole and an opening,
The movable contact is formed of a member in which two cylindrical portions having different outer diameters are integrally formed, and of the two cylindrical portions having different outer diameters, the cylindrical portion having the thicker diameter is the storage chamber. The gas-insulated switchgear according to any one of claims 6 to 9, wherein the gas-insulated switchgear is formed so as to be accommodated in a cylindrical shape, and a cylindrical portion having a smaller diameter is slidably attached to the opening of the partition wall. The movable contact base is formed with an intake hole communicating the internal space of the pressure vessel and the compression chamber,
The gas-insulated switchgear according to any one of claims 6 to 10, wherein a valve that closes the intake hole due to a pressure difference when the pressure in the compression chamber becomes higher than the pressure in the internal space of the pressure vessel is attached to the intake hole. . The movable contact is attached with an arc-resistant metal at a portion in contact with the fixed contact,
The gas insulated switchgear according to any one of claims 1 to 11, wherein a vent hole communicating with the hollow portion is formed in the arc-resistant metal.

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