The present invention relates to a gas circuit breaker for the power having an extinguishing gas, and particularly relates to an exhaust structure on a movable side of a circuit breaker part.
In recent years, the capacity of a circuit breaker is increased as voltage/current of a power system is increased, but a request for reducing cost and space by optimizing the structure of the circuit breaker part is increased, and it is required to secure excellent circuit-breaking performance with a lower operating force.
Gas circuit breakers including a thermal puffer type circuit breaker generally includes a puffer shaft connecting a movable-side circuit breaker part formed of a puffer cylinder, an insulating nozzle, a movable main contact and a movable arc contact to an insulating rod, and a gas passage is provided inside the puffer shaft.
The gas passage is provided for the purpose of spraying an extinguishing gas compressed in the puffer cylinder on the arc generated between the movable arc contact and a stationary arc contact, then, exhausting the gas to the movable side of the circuit breaker part.
The extinguishing gas passing through the gas passage of the puffer shaft is heated by the arc and contacts particles of a nozzle material and an electrode material melted by the arc, therefore, the gas has a high temperature and is contaminated. Due to the extinguishing gas with the high temperature (hereinafter referred to as a hot gas), the surface of the insulating rod or the inside of an insulation cylinder may be burned and carbonized, or conductive foreign substances may stick, which may drastically reduce the insulation performance and may cause a ground fault.
In Patent Literature 1, there is disclosed a gas circuit breaker including a puffer shaft coupled to an insulation rod side through a shaft guide and an exhaust cylinder provided inside a movable-side main circuit conductor so as to surround the insulation rod, in which a piston ring provided in an outer periphery of the shaft guide slides inside the exhaust cylinder. The invention contributes to the improvement in insulation performance of the gas circuit breaker by blocking a flow path through which the hot gas flows toward the insulation rod and the insulation cylinder.
Patent Literature 1: JP-A 2013-125720
As a gap between the exhaust cylinder and the shaft guide is completely blocked with the piston ring in the gas circuit breaker disclosed in Patent Literature 1, the piston ring slides while directly contacting an inner surface of the exhaust cylinder, therefore, slight sliding resistance is generated. Moreover, as the shaft guide has an outer diameter which is approximately equal to an inner diameter of the exhaust cylinder, a certain degree of size and rigidity may be necessary. An object of the present invention is to provide a gas circuit breaker capable of protecting the insulation rod and the insulation cylinder from the hot gas, improving the insulation performance and realizing smooth breaking operation with a lighter and simpler structure.
According to an embodiment of the present invention, there is provided a gas circuit breaker having an insulation tank filled with an extinguishing gas, a pair of a stationary-side main circuit conductor and a movable-side main circuit conductor provided in insulation tank, a stationary-side contact and a movable-side contact provided between the stationary-side main circuit conductor and the movable-side main circuit conductor so as to be separated, a puffer cylinder having the movable-side contact at one end, a puffer chamber formed in the puffer cylinder, an insulation nozzle forming a flow path for leading the extinguishing gas in the puffer chamber to arc generated between the movable-side contact and the stationary-side contact, a puffer shaft having a gas passage for leading the extinguishing gas led to the arc to the movable side of a circuit breaker part and exhausting the gas, and an insulation rod coupled to the puffer shaft, which includes a hot gas blocking member at a joint between the puffer shaft and the insulation rod.
According to the present invention, the improvement in insulation performance and circuit-breaking performance of the gas circuit breaker can be realized with a simple structure
Hereinafter, embodiments of the present invention will be explained with reference to the drawings. The following are lust examples and do not intend to limit the contents of the invention to the following specific examples. The invention itself may be achieved in various manners in conformity with the contents described in claims.
An extinguishing gas such as an SF6 gas is sealed in an insulation tank 1, and a stationary-side live conductor 11 and a movable-side live conductor 21 are drawn into the tank.
The stationary-side live conductor 11 is electrically connected to a stationary-side main circuit conductor 12, a stationary arc contact base 13, a stationary arc contact 14 and a stationary main contact 15 which configure a stationary-side circuit breaker part 10.
The movable-side live conductor 21 is electrically connected to a circuit-breaker part movable portion 30 through a movable-side main circuit conductor 22, a sliding contact 23 and a puffer cylinder 31.
A stationary piston is disposed inside the movable-side main circuit conductor 22, and an inner cylinder surface of the puffer cylinder 31 is supported by a puffer cylinder supporting sliding guide 25 attached to an outer periphery of the stationary piston 24. The sliding contact 23 is provided in an inner periphery of the movable-side main circuit conductor 22, which contact an outer cylinder surface of the puffer cylinder 31. According to the structure, the puffer cylinder 31 can move in an axial direction while maintaining electrical connection through the movable-side main circuit conductor 22 and the sliding contact 23.
A through hole is provided in the center of the stationary piston 24, and a puffer shaft 32 having a gas passage 41 thereinside is disposed inside the stationary piston 24 so as to slide freely. The puffer shaft 32 is supported by a puffer-shaft supporting sliding guide 26 attached in an inner periphery of the stationary piston 24.
One end of the puffer shaft 32 is fixed to the puffer cylinder 31 and the other end of the puffer shaft 32 is coupled to one end of an insulation rod 34 through a circuit-breaker side coupling pin 33. The other side of the insulation rod 34 is coupled to a lever 36 housed in a mechanism case 2 provided adjacent to the insulation tank 1 through a lever-side coupling pin 35.
A shaft 37 of the lever 36 is supported by the mechanism case 2 so as to rotate freely. The lever 36 is connected to an actuator (not shown) on the outside of the mechanism case 2 through the shaft 37. The lever 36 rotates by a drive force of the actuator, and the circuit breaker part movable portion 30 moves in the axial direction.
A movable arc contact 51 is provided in the center of a tip portion of the puffer cylinder 31. An insulation cover 52, an insulation nozzle 53 and a movable main contact 54 are respectively arranged in a concentric manner so as to surround an outer periphery of the movable arc contact 51.
The movable arc contact. 51 has a through hole, which is connected to the gas passage 41 inside the puffer shaft 32 through the puffer cylinder 31. The gas passage 41 of the puffer shaft 32 extends to the vicinity of a joint between the puffer shaft 32 and the insulation rod 34, opening at an opening A 42 on a cylinder surface of the puffer shaft 32 in a radial direction.
The movable-side main circuit conductor 22 is supported by an insulation cylinder 27 fixed to the insulation tank 1. The movable-side main circuit conductor 22 has an opening B 43 on a side surface, which communicates into the insulation tank 1. The movable-side main circuit conductor 22 has a guard cylinder 29 thereinside close to the insulating cylinder 27 and an exhaust cylinder 28 close to the stationary piston 24. The guard cylinder 29 and the exhaust cylinder 28 are fixed to an inner wall of the movable-side main circuit conductor 22 and the stationary piston 24 by means of, for example, bolt fastening.
The insulation rod 34 is disposed inside the exhaust cylinder 28, the guard cylinder 29 and the insulation cylinder 27 so as to move freely in the axial direction. The joint between the puffer shaft 32 and the insulation rod 34 housed inside the exhaust cylinder 28 is covered with an insulation rod cover 38.
A pin portion 61 of the circuit-breaker side coupling pin 33 penetrates through a pin hole of the puffer shaft 32 and a pin hole of the insulation rod 34, and the puffer shaft 32 and the insulation rod 34 are coupled so as to rotate freely around an axis of the circuit-breaker side coupling pin 33.
The circuit-breaker side coupling pin 33 is formed of a female screw component 63 and a male screw component 64. The female screw component 63 includes an insulation rod cover support portion A 62 and the pin portion 61 having a female screw portion. The male screw component 64 includes an insulation rod cover support portion B 65 and a male screw portion. The circuit-breaker side coupling pin 33 has a structure in which the female screw component 63 is combined with the males screw component 64 by screwing and so on, which can be assembled and disassembled from both sides of the pin hole. In the description, the combined structure is referred to as a divided structure.
The insulation rod cover 38 is a cylindrical member having a size to be housed inside the exhaust cylinder 28 and the guard cylinder 29, which is made of PTFE (polytetrafluoroethylene). Materials other than PTFE may be used as long as materials have excellent heat durability and mechanical strength and are light in weight.
An end portion of the puffer shaft 32 is fitted to the insulating rod cover 38. On an outer cylinder surface of insulating rod cover 38, there is formed a through hole a diameter of which is slightly larger than the insulation rod cover support portion A 62 and the insulation rod cover support portion B 65 of the circuit-breaker side coupling pin 33. As the insulation rod cover support portion A 62 and the insulation rod cover support portion B 65 of the circuit-breaker side coupling pin 33 are fitted to the through hole, the insulating rod cover 38 is held by the circuit-breaker side coupling pin 33. That is, the insulating rod cover 38 is held by the end portion of the puffer shaft 32 and the circuit-breaker side coupling pin 33 so as to cover the joint between the puffer shaft 32 and the insulation rod 34.
As the structure of covering the joint is adopted as described above, it is possible to prevent foreign substances carried by a hot gas from sticking to the joint between the puffer shaft 32 and the insulation rod 34, therefore, a later-described vertical motion of the insulation rod 34 can be maintained to be smooth.
Moreover, as the structure of holding the insulation rod cover is adopted as described above, it is possible to prevent the insulation rod cover from falling off due to an impact of a circuit-breaking operation. Therefore, the reliability of the circuit breaker can be improved.
The structure of the insulation rod cover 38 is an example of the member for blocking the hot gas. The structure in which foreign substances carried by the hot gas can be prevented from sticking to the joint between the puffer shaft 32 and the insulation rod 34 as well as the insulation rod cover can be prevented from falling off can be applied to the circuit breaker according to the present invention, not being limited to the above insulation rod cover 38.
The insulation rod cover 38 moves along inner surfaces of the exhaust cylinder 28 and the guard cylinder 29 with the circuit-breaker side coupling pin 33 when the circuit breaker part movable portion 30 moves. When the drive force of the actuator (not shown) is transmitted to the lever 36 through the shaft 37 and the lever 36 moves in an arc, the insulation rod 34 vertically moves slightly with the circuit-breaker side coupling pin 33 as a fulcrum. An inner diameter of the opening of the insulation rod cover 38 on the side not fitted to the puffer shaft 32 is formed to be a size not interfering with the exhaust cylinder 28 and the guard cylinder 29 even when the insulation rod 34 vertically moves.
It is preferable to form the fitted portion between the insulation rod cover 38 and the puffer shaft 32 with a gap as small as possible for preventing the infiltration of the hot gas from the circuit breaker part.
The structure of the embodiment will be explained based on the circuit-breaking operation.
In this state, the inside of a throat portion 45 as the minimum diameter portion of the insulation nozzle 53 and the movable arc contact 51 is almost blocked by the stationary arc contact 14, and the opening A 42 of the puffer shaft 32 is closed as it is positioned inside the stationary piston 24. The insulation rod cover 38 is also housed inside the exhaust cylinder 28.
When the circuit breaker part movable portion 30 moves to the movable side by the circuit-breaking operation from the state shown in
When the circuit-breaking operation proceeds after the movable arc contact 51 and the stationary arc contact 14 are separated to be a state shown in
In the structure of the embodiment, the hot gas exhausted from the opening A 42 of the puffer shaft 32 is first released to the space D 46 formed by the exhaust cylinder 28 and the insulation rod cover 38. The hot gas exhausted from the opening A 42 has a high temperature and contains particles of a nozzle material or an electrode material melted by the arc.
The insulation rod 34 is generally formed of a GFRP (glass fiber reinforced plastic) coated with an extinguishing-gas resistance film. When the hot gas is directly sprayed on the insulation rod 34, the coating on the surface may be burned and the insulation performance may be reduced. Moreover, when particles of the electrode material and so on contained in the hot gas are fused into a slight gap existing between the circuit-breaker side coupling pin 33 and the insulation rod 34 as well as between the lever-side coupling pin 35 and the insulation rod 34, the smooth circuit-breaking operation may be inhibited.
The gas circuit breaker according to the embodiment can prevent the reduction of the insulation performance in the insulation rod 34 as it is possible to prevent the hot gas from being directly sprayed onto the insulation rod 34 due to the insulation rod cover 38. It is also possible to prevent the above-described particles from sticking to the joint portion between the insulation rod 34 and the puffer shaft 32, therefore, the smooth circuit-breaking operation can be realized.
On the other hand, the structure of the present invention including the exhaust cylinder 28, the insulation rod cover 38 and the guard cylinder 29 also contributes to the improvement in circuit-breaking performance as described below.
As shown in
As the circuit-breaking operation further proceeds and the stationary arc contact 14 comes off from the throat portion 45, or the gap E 47 becomes sufficiently large as shown in
In the state shown in
In the structure of the embodiment, the insulation rod cover 38 moves to the inside of the guard cylinder 29 in a last half of the circuit-breaking operation. As the area of a gap F 48 between the guard cylinder 29 and the insulation rod cover 38 is sufficiently smaller than the area of the opening B 43, she flow path resistance is high and the flowing of the hot gas into the insulation cylinder 27 can be suppressed. Accordingly, it is possible to prevent the insulation rod 34 and the insulation cylinder 27 from being contaminated by the hot gas, therefore, the reduction in the insulation performance can be prevented.
In the description, while the stationary arc contact 14 moves in the throat portion 45 of the insulation nozzle 53 from the start of the circuit-breaking operation (namely, a period of the circuit-breaking operation in which the pressure of the extinguishing gas inside the puffer cylinder 31 is increased) is defined as a first half of a circuit-breaking operation. A period in which the circuit-breaking operation is completed after the stationary arc contact 14 comes off from the throat portion 45 of the insulation nozzle 53 is defined as a last half of a circuit-breaking operation.
Another embodiment of the present invention will be explained with reference to
In Example 2, the exhaust cylinder 28 is extended so that a length of a gap between the exhaust cylinder 28 and the guard cylinder 29 is approximately equal to a length of the insulation rod cover 38 in the axial direction, and an exhaust hole C 44 is provided on a side surface of the exhaust cylinder 28.
In the structure in which the exhaust cylinder 28 is extended as shown in
When the exhaust cylinder 28 is simply extended, the hot gas accumulated in the space D 46 inside the exhaust cylinder 28 is not released and there is a risk that the temperature inside the exhaust cylinder 28 is drastically increased and the circuit-breaking performance is reduced. In response to this, the exhaust hole C 44 is provided on the side surface of the exhaust cylinder 28 and the hot gas accumulated in the space D 46 inside the exhaust cylinder 28 is released from the exhaust hole C 44 on the side surface during the circuit breaking operation, thereby preventing the reduction of the circuit-breaking performance.
The above explanation has been made by citing the machine-puffer type as circuit breaker as an example, however, the present invention can be naturally applied to dual-chamber puffer type gas circuit breaker, and the above advantages can be obtained also when the present invention is applied to the dual-chamber puffer type gas circuit breaker.
Number | Date | Country | Kind |
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2014-101903 | May 2014 | JP | national |
Filing Document | Filing Date | Country | Kind |
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PCT/JP2015/056029 | 3/2/2015 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO2015/174122 | 11/19/2015 | WO | A |
Number | Name | Date | Kind |
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4467158 | Kobayashi | Aug 1984 | A |
5151566 | Koyanagi | Sep 1992 | A |
5977502 | Mizoguchi | Nov 1999 | A |
9058947 | Yaginuma | Jun 2015 | B2 |
20020113040 | Imamura | Aug 2002 | A1 |
20100147804 | Yamada | Jun 2010 | A1 |
20150053647 | Yoshitomo | Feb 2015 | A1 |
20150060411 | Yamashita | Mar 2015 | A1 |
Number | Date | Country |
---|---|---|
1372287 | Oct 2002 | CN |
2013-125720 | Jun 2013 | JP |
Entry |
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International Search Report (PCT/ISA/210) issued in PCT Application No. PCT/JP2015/056029 dated Apr. 21, 2015 with English translation (Two (2) pages). |
Japanese-language Written Opinion (PCT/ISA/237 issued in PCT Application No. PCT/JP2015/056029 dated Apr. 21, 2015 (Four (4) pages). |
Chinese-language Office Action issued in counterpart Chinese Application No. 201580018816.X dated Jun. 7, 2017 (Ten (10) pages). |
Number | Date | Country | |
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20170148591 A1 | May 2017 | US |