The present application claims priority from Japanese patent application serial No. 2011-280704, filed on Dec. 22, 2011, the content of which is hereby incorporated by reference into this application.
1. Technical Field
The present invention relates to gas circuit breaker, and particularly to a gas circuit breaker having operating mechanism with improved insulation performance.
2. Background Art
Since breaking capacity of circuit breakers used in substations and switchyards has increased due to enlarged capacity of recent transmission systems, large capacity gas circuit breakers configured in such a way that two breaking sections are opened and closed with an actuator (hereinafter referred to as double-break gas circuit breakers) are often-used.
In
A connecting pin 6 is inserted into second end part of the insulated operating rod 5, and first ends of links 7 at front and rear sides of paper of the insulated operating rod 5 are connected by means of the connecting pin 6. Second ends of the pair of links 7 are connected by another connecting pin 8, putting a triangle lever 9 between the links 7. The triangle lever 9 is connected to the movable part of the breaking section on the left of paper.
{Patent Literature 1}
Japanese Patent Laid-Open No. 2010-232032
As described above, the operating mechanism of the double-break gas circuit breaker has the complicated link mechanism. In addition, since the double-break gas circuit breaker needs to break heavy-current at high speed, it must operate the link mechanism with large operating force. For this reason, conductive particles are generated at sliding section of the link mechanism, and if the conductive particles adhere to the insulation support cylinder that maintains insulation between charged section and the actuator side, dielectric strength of the equipment deteriorates, and, in worst case, breakdown may be caused.
Moreover, the conductive particles are generated by breaking operation of each of the two breaking sections and are exhausted together with exhaust hot gas that is generated at the breaking sections. Since the breaking sections are oppositely arranged, the exhaust hot gas flows oppositely, mixes around the operating link mechanism located midway, and flows into space inside the insulation support cylinder. If this causes adhesion of the conductive particles onto the insulation support cylinder, dielectric strength of the equipment deteriorates, and, in the worst case, breakdown may be caused the same as above.
In view of these problems, an object of the present invention is to provide a gas circuit breaker for preventing the conductive particles that are generated at the time of breaking operation from adhering to the insulation support cylinder and improving insulation performance of the equipment.
A gas circuit breaker of the present invention comprising: a sealed tank filled with insulation gas therein; two breaking sections disposed in the sealed tank respectively; a bracket to support movable parts of the breaking sections configuring the two breaking sections while enabling switching operation of the movable parts of the breaking sections; an insulation cylinder to support the bracket through an electric field relaxation shield; an insulated operating rod disposed in the insulation cylinder movably in the axial direction and a first end thereof is connected to an actuator; and a link mechanism connected to a second end of the insulated rod and transmits drive force from the actuator to the movable parts of the breaking sections, wherein the electric field relaxation shield is provided with an out-side groove part and an in-side groove part on out-side and in-side of the insulation cylinder respectively, and the out-side groove part and the in-side groove part are formed openings at the link mechanism side respectively, and an end of the in-side groove part is extended to near the out-side of the insulated operating rod.
“Link mechanism” here is mechanism that is located between the insulated operating rod and the movable parts of the breaking sections and that changes axial direction movement of the insulated operating rod caused by the actuator into axial direction movement of the movable parts of the breaking sections.
Preferably, the electric field relaxation shield is characterized by having a hollow center and circular truncated cone shaped cover at the end of the in-side groove part.
Moreover, preferably, the insulated operating rod is characterized in that the operating rod has a ring shaped guide at a second end at the link mechanism side, and the guide is located above the end of the in-side groove part at the time of open action completion.
According to the present invention, reliability of gas circuit breaker can be improved because high temperature and high pressure gas flow containing the conductive particles generated at the link mechanism and the conductive particles generated at the breaking sections due to arc are prevented from flowing into the insulation support cylinder by the electric field relaxation shield that has a function of a particle trap.
Hereinafter, a first embodiment of gas circuit breaker in the present invention is described with reference to the drawings. In
Movable parts of breaking sections 20 are retained at both sides of the bracket 3. More particularly, puffer cylinders 6, which are the movable parts of breaking sections 20, are slidably supported by fixed pistons 7 and the fixed pistons 7 are fixed to both sides of the bracket 3 to form a double-break circuit breaker. The actuator 2 is located outside the sealed tank 1. A first end of insulated operating rod 13 is connected to the actuator 2, and the puffer cylinder 6 is connected to a second end of the insulated operating rod 13 through the operating link mechanism 30. The insulated operating rod 13 transmits operating force from the actuator 2 to the movable parts 6 of breaking sections 20 while retaining electrical insulation between the actuator 2 and the movable parts 6 of the breaking sections 20.
For the bracket 3, various shapes and structures can be adopted. As shown in
As described above, the bracket 3 is supported by the insulation support cylinder 5 through the electric field relaxation shield 4. The electric field relaxation shield 4 is constituted to have an out-side groove part 4a, an in-side groove part 4b, and a disk part 4c for connecting the both groove parts 4a and 4b in order to capture conductive particles 16 generated by the operation of the operating link mechanism 30 configured by above-mentioned connecting pins 9a, 9b, 9c, and 9d, links 8 and 12, and triangle lever 11. The electric field relaxation shield 4 is in the form of a ring, and the out-side groove part 4a thereof is arranged at the out-side of the insulation support cylinder 5 and the in-side groove part 4b thereof is arranged at the in-side of the insulation support cylinder 5. Each groove parts 4a, 4b has an opening that faces to the operating link mechanism 30. The insulated operating rod 13 passes movably in the axial direction through inside the in-side groove part 4b of the electric field relaxation shield 4.
Since the insulated operating rod 13 moves vertically inside the in-side groove part 4b of the electric field relaxation shield 4, clearance 15 is arranged between the insulated operating rod 13 and the in-side groove part 4b. However, in order to prevent the conductive particles 16 from falling into and adhering to the inside of the insulation support cylinder 5, the in-side groove part 4b is approximated to the insulated operating rod 13 to a maximum extent under the condition that the insulated operating rod 13 and the in-side groove part 4b do not touch mutually. In addition, the electric field relaxation shield 4 is preferable to be made of aluminum, which is excellent in conductivity, like electric field relaxation shields used ordinarily.
After the conductive particles 16 fell onto the out-side groove part 4a or the in-side groove part 4b, because the conductive particles 16 are covered with the electric field relaxation shield 4, the conductive particles 16 become less affected by electric force caused by electric field. As a result, scattering risk of the conductive particles 16 from the groove part 4a or 4b is reduced, whereby insulation performance of the equipment is maintained in a good state.
Also when the conductive particles 16 that fell down onto the bolt leap above the out-side groove part 4a side, the conductive particles 16 fall down into the out-side groove part 4a of the electric field relaxation shield 4 to be captured. As seen above, since the electric field relaxation shield 4 can capture the conductive particles 16 into the out-side groove part 4a and the in-side groove part 4b, insulation performance deterioration of the gas circuit breaker by the conductive particles 16 can be prevented.
In contrast, in a traditional structure having electric field relaxation shield without the function described above, because high temperature and high pressure exhaust gas containing the conductive particles generated at the operational link mechanism and the conductive particles generated at the breaking section when current is broken flows through both sides of the operating mechanism toward the insulated operating rod, there has been a risk that insulation performance is adversely affected by inflow of the high temperature and high pressure gas containing the conductive particles into the insulation support cylinder that stores the insulated operating rod.
In the structure of the present embodiment, the high temperature and high pressure gas flow containing the conductive particles 16 generated at the operating link mechanism 30 and the conductive particles 16 generated at the breaking sections 20 due to arc is prevented from flowing into the insulation support cylinder 5 by the electric field relaxation shield 4, and prevented from directly blowing toward the out-side of the insulation support cylinder 5.
With that, adhesion of the conductive particles on the insulation support cylinder 5 can be prevented, whereby reliability of gas circuit breakers can be further improved.
Hereinafter, the second embodiment of gas circuit breaker in the present invention is described based on
Circular end of the in-side groove part 4b of the electric field relaxation shield 4 is screwed so as to fix a cover 14. In addition, a larger diameter side 14b of the cover 14 is also screwed so as to be fixed to the end of the in-side groove part 4b of the electric field relaxation shield 4 with screw clamp. When this is done, the larger diameter side 14b of the cover 14 can be fixed to the end of the in-side groove part 4b of the electric field relaxation shield 4 with screw clamp, whereby assemblage can be made easy.
In order to prevent the conductive particles 16 from getting into the insulation support cylinder 5, a clearance between a smaller diameter side 14a of the cover 14 and the insulated operating rod 13 is preferably narrowed to a maximum extent. However, the insulated operating rod 13 and the smaller diameter side 14a of the cover 14 are arranged so as not to touch with each other.
In the structure of the present embodiment, the end of the in-side groove part 4b of the electric field relaxation shield 4 made of aluminum needs to be circular in consideration of electric field relaxation. As shown in
Hereinafter, a third embodiment of gas circuit breaker in the present invention is described based on
An electric field relaxation shield 4 is fixed to the insulation support cylinder 5. The electric field relaxation shield 4 is configured by an out-side groove part 4a, an in-side groove part 4b, and a disk part 4c like the first embodiment, but end of the in-side groove part 4b is arranged at lower position compared to the first embodiment so as not to interfere with the vertical movement of the guide 17.
By means of the structure described above, the conductive particles that fell down from the operating link mechanism 30 side into the insulation support cylinder 5 are prevented from intruding into the insulation support cylinder 5 by means of the guide 17, and finally captured into the in-side groove part 4b. That is to say, the risk of the conductive particles adhering to the inside of the insulation support cylinder 5 can be reduced, whereby reliability of gas circuit breakers can be improved.
Number | Date | Country | Kind |
---|---|---|---|
2011-280704 | Dec 2011 | JP | national |
Number | Name | Date | Kind |
---|---|---|---|
3899650 | Kishi et al. | Aug 1975 | A |
3946184 | Yoshioka et al. | Mar 1976 | A |
4101748 | Meyer et al. | Jul 1978 | A |
4251701 | Meyer | Feb 1981 | A |
4307273 | Sasaki et al. | Dec 1981 | A |
4433293 | Aoyagi et al. | Feb 1984 | A |
4434333 | Kawasaki | Feb 1984 | A |
5191180 | Kitamura et al. | Mar 1993 | A |
5483031 | Matsuda | Jan 1996 | A |
5495084 | Meyer et al. | Feb 1996 | A |
5604340 | Yamada et al. | Feb 1997 | A |
5654532 | Meyer et al. | Aug 1997 | A |
6624370 | Soga et al. | Sep 2003 | B1 |
6660954 | Iwabuchi et al. | Dec 2003 | B2 |
Number | Date | Country |
---|---|---|
1087202 | May 1994 | CN |
1117199 | Feb 1996 | CN |
2224460 | Apr 1996 | CN |
09-259712 | Oct 1997 | CN |
101807777 | Aug 2010 | CN |
201601078 | Oct 2010 | CN |
102013356 | Apr 2011 | CN |
09-134651 | May 1997 | JP |
2010-232032 | Oct 2010 | JP |
Entry |
---|
Chinese Office Action received in corresponding Chinese Application No. 201210550247 dated Sep. 3, 2014. |
Number | Date | Country | |
---|---|---|---|
20130161290 A1 | Jun 2013 | US |