KR200309286Y1 - Vacuum interrupter of a vacuum circuit breaker - Google Patents

Abstract

The present invention is to reduce the mechanical shock applied to the vacuum interrupter, which is a core part of the breaker during the opening and closing operation of the vacuum circuit breaker, vacuum switch, etc., the application of vacuum, so that the impact is not transmitted to the surroundings including the seal cup and the insulating container. It relates to a vacuum interrupter of the vacuum breaker.

The vacuum interrupter of the vacuum interrupter has a movable side conducting electrode connected to the tip of the insulating rod, and a fixed side conducting electrode is connected to the terminal at a lower side corresponding to the movable side conducting electrode. The movable side conducting electrode and the fixed side conducting electrode are provided inside the insulated container, and upper and lower ends of the insulated container are provided with a thread cup, and a corrugated pipe is connected to the upper movable side seal cup. The lower fixed side seal cup connects the fixed side conducting electrode and the insulating container, and an impact buffer member including a corrugated pipe is formed between the fixed side seal cup and the fixed side conducting electrode.

According to the present invention having the above constitution, deformation and cracks of the vacuum interrupter are absorbed in advance by the impact energy transmitted to the fixed side seal cup and the insulating container by the shock buffer member for absorbing the impact energy during opening and closing operation of the mechanism part of the vacuum interrupter. This is prevented as well as the vacuum tightness of the vacuum breaker accordingly is ensured has the effect of improving the reliability of the vacuum breaker.

Description

Vacuum interrupter of a vacuum circuit breaker

The present invention relates to a vacuum interrupter of a vacuum breaker, and more particularly, in order to prevent the mechanical shock applied to the vacuum interrupter, which is a core part of the breaker, during opening and closing operations such as a vacuum breaker and a vacuum switch to which a vacuum is applied, to prevent it from being transferred to the surroundings. It relates to a vacuum interrupter of a vacuum breaker.

In general, circuit breakers and switchgear are devices that directly control the power supply to the load by opening and closing the electric circuits in the power system, ranging from the load current to the fault current, to the switchgear that opens and closes the load current. It is widely used. These breakers are classified into hydraulic breakers, air breakers, gas breakers and vacuum breakers according to the insulating medium of the core. Among these, the vacuum circuit breaker is small, has high reliability, has excellent frequency opening and closing properties, and is easy to maintain, and has been widely used in medium voltage to high voltage large capacity.

The structure of the vacuum interrupter 100, which is a block of a conventional vacuum circuit breaker, is shown in FIG. In the configuration of the electric interrupter 100, the movable side conducting electrode 12 of the vacuum interrupter 100 is connected to the tip of the insulating rod 10 for transmitting the mechanical energy of the vacuum breaker, the movable conducting electrode 12 The movable contact 16 is formed in the edge part. The lower side corresponding to the movable side conducting electrode 12 is provided with a fixed side conducting electrode 20 connected to the terminal 28, the end of the fixed side conducting electrode 20 and the movable contact 16 and The fixed contact 18 which comes into contact is formed. These movable side conducting electrodes 12, the movable contact 16, the fixed contact 18, and the fixed side conducting electrode 20 are provided on the same straight line.

The movable side conducting electrode 12 and the fixed side conducting electrode 20 are provided inside the ceramic insulating container 14, and the upper and lower ends of the insulating container 14 are referred to as seal cups (22, 24). The upper movable side seal cup 22 is connected to a corrugated pipe 26 called bellows, and the corrugated pipe 26 is connected to the movable side conducting electrode 12. The lower fixed side seal cup 24 connects the fixed side conducting electrode 20 and the ceramic insulating container 14. In addition, the metal member has a cylindrical shape, and is configured to include a shield member 30 disposed to be spaced apart from the movable contact 16 and the fixed contact 18 by a predetermined distance.

In the conventional vacuum interrupter 100 configured as described above, mechanical impact energy generated during the opening and closing operation of the vacuum circuit breaker is transmitted in the following order.

First, the mechanical shock energy transmitted through the insulating rod 10 during the opening and closing operation of the vacuum circuit breaker is transmitted to the movable side conducting electrode 12 which plays a role of opening and closing the contact, and at the same time, the movable contact 16 and the fixed contact. The fixed side conducting electrode 20 and the fixed side terminal 28 are delivered in order through the contact 18.

As such, when the mechanical shock energy transmitted through the movable side conducting electrode 12 reaches the fixed side conducting electrode 20, the mechanical impact energy is applied to the fixed side conducting electrode 18 as well as the fixed side terminal 28. It is also delivered to the connected metal seal cup 24 and the ceramic insulating container 14. As such, the mechanical impact energy transmitted to each connection part and component may cause deformation and cracks, as well as a problem of adversely affecting the vacuum tightness of the vacuum circuit breaker.

That is, the detailed structure of the fixed side conducting electrode 20 and the fixed side seal cup 24 of FIG. 2 can be seen, in which the fixed side seal cup 24 is in close contact with the fixed side conducting electrode 20. The airtightness is maintained, and one end is coupled to the insulating container 14. Since the fixed side conducting electrode 20, the fixed side seal cup 24, and the insulating container 14 are closely coupled, it can be seen that the impact is propagated to all the portions when an impact is applied to any one portion.

The mechanical impact energy is increased in the breaking capacity required by the vacuum circuit breaker, the mechanical current of the movable side conducting electrode 12 and the fixed side conducting electrode 18 is mechanically in contact with the vacuum interrupter 100 during the opening and closing operation due to the increase of the impact energy. The mechanical stress (impact) applied to) becomes high. At this time, it is necessary to minimize the mechanical impact energy delivered to the vacuum interrupter, in particular, the fixed side seal cup 24 and the insulating container 14 which maintain airtightness, and when the mechanical impact energy cannot be solved, the above-described deformation and cracks are generated. This causes a problem that the airtightness of the insulating container 14 is not maintained.

An object of the present invention for solving the above problems is to buffer the shock absorber so that the shock is not directly transmitted to the fixed side seal cup and the insulating container connected to the fixed side conducting electrode when the mechanical impact energy reaches the fixed side conducting electrode. It is to provide a vacuum interrupter of the vacuum breaker.

Another object of the present invention is to provide a shock absorbing member for absorbing the impact energy during opening and closing operation of the mechanical part of the vacuum interrupter, so that the mechanical impact energy delivered to the fixed side seal cup and the insulating container is absorbed in advance to prevent deformation and cracking of the vacuum interrupter. It is to provide a vacuum interrupter of the vacuum breaker to prevent.

1 is a view showing the configuration of a vacuum interrupter of a conventional vacuum circuit breaker

FIG. 2 is a view illustrating a structure of a fixed side conducting electrode and a fixed side seal cup part of FIG. 1; FIG.

3 is a view showing an embodiment of a vacuum interrupter of the vacuum breaker according to the present invention

4 is a view showing a structure in which a corrugated pipe is attached to a fixed side conducting electrode and a fixed side seal cup part of FIG.

<Description of Symbols for Main Parts of Drawings>

100, 200: vacuum interrupter 10: insulated rod

12: movable electrode conduction electrode 14: insulation container

16: movable contact 18: fixed contact

20, 44: fixed side conducting electrode 22, 24, 42: seal cup

26, 40: corrugated pipe 28: terminal

30: shield member

The vacuum interrupter of the vacuum circuit breaker according to the present invention for realizing the above object includes a movable side conducting electrode connected to an insulating rod for transferring mechanical energy, a lower fixed side conducting electrode corresponding to the movable side conducting electrode, and the movable portion. Insulation container through which the side conducting electrode and the fixed side conducting electrode are inserted into the center, and the movable side and the fixed side seal cup which are combined with the movable side conducting electrode and the fixed side conducting electrode and the insulation container to maintain airtightness. In the vacuum interrupter of the vacuum circuit breaker configured, an impact buffer member is formed between the fixed side conducting electrode and the fixed side seal cup.

According to a preferred example of the present invention, the impact buffer member may include a corrugated pipe, it may be composed of a corrugated pipe of a metal material or rubber material.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

The configuration according to the embodiment of the present invention devised to buffer the mechanical shock transmitted to the fixed side portion of the vacuum interrupter, which is the main circuit breaker of the vacuum circuit breaker, is transmitted to the fixed side metal seal cup and the ceramic insulated container. It is. The same components as those of FIG. 1 have the same reference numerals, and detailed description thereof will be omitted.

In the vacuum interrupter 200 of the vacuum interrupter according to the present embodiment, the movable side conducting electrode 12 of the vacuum interrupter 200 is connected to the tip of the insulating rod 10 that transmits the mechanical energy of the vacuum breaker. A movable contact 16 is formed at the end of the side conducting electrode 12. The lower side corresponding to the movable side conducting electrode 12 is provided with a fixed side conducting electrode 44 connected to the terminal 28, and the movable contact 16 and the end of the fixed side conducting electrode 44 are provided. The fixed contact 18 which comes into contact is formed. The movable side conducting electrode 12, the movable contact 16, the fixed contact 18, and the fixed side conducting electrode 44 are provided on the same straight line.

The movable side conducting electrode 12 and the fixed side conducting electrode 44 are provided inside the ceramic insulating container 14, and the metal cups 22 and 42 are provided at upper and lower ends of the insulating container 14, respectively. The upper movable side seal cup 22 is connected to the corrugated pipe 26, and the corrugated pipe 26 is connected to the movable side conducting electrode 12. In addition, the lower fixed side seal cup 42 connects the fixed side conducting electrode 44 and the ceramic insulating container 14, and between the fixed side seal cup 42 and the fixed side conducting electrode 44, a corrugated pipe ( 40) is formed. In addition, the metal material has a cylindrical shape, and includes a shield member 30 disposed to be spaced apart by a predetermined distance around the movable contact 16 and the fixed contact 18.

According to the embodiment of the present invention configured as described above, when the mechanical energy of the vacuum circuit breaker is transferred to the insulating rod 10, the movable contact 16 formed at the end thereof is moved while the movable side conducting electrode 12 is lowered. It comes into contact with the fixed contact 18 of the fixed side conducting electrode 44 formed on the lower side. At this time, the movable contact 16 and the fixed contact 18 is instantaneously contacted, and thus mechanical impact energy is transmitted to the fixed side seal cup 42 and the terminal 28 through the fixed side conducting electrode 44.

However, the strength of the mechanical impact energy acting on the fixed side seal cup 42 and the terminal 28 is corrugated pipe 40 formed between the fixed side seal cup 42 and the lower end of the fixed side conducting electrode 44. Since it is weakened through the mechanical impact energy does not reach the fixed side seal cup 42 and the insulating container (14).

That is, referring to FIG. 4 where a more detailed structure of the corrugated pipe 40 is illustrated, the corrugated pipe 40 is formed at a portion where the fixed side conducting electrode 44 and the fixed side seal cup 42 are spaced apart from each other by a predetermined interval. The corrugated pipe 40 is coupled to the lower end of the fixed side conducting electrode 44 to mitigate mechanical shock and to maintain airtightness. As such, the insulating container 14 connected to the fixed side seal cup 42 is not affected by the mechanical impact energy by the corrugated pipe 40 that absorbs mechanical shock.

The corrugated pipe 40 according to the present embodiment may have various forms, and may have sufficient characteristics to absorb shocks, as well as to maintain airtightness. For example, a metal hermetic corrugated pipe having an airtight characteristic of a metal material may be used, and the metal hermetic corrugated pipe has many cases in which a manufacturing environment or a use environment of the vacuum interrupter 200 is formed at a high temperature. It can be used as appropriate.

In addition, the corrugated pipe 40 may not exclude the use of a corrugated pipe made of a special rubber material having heat resistance. In addition, the present invention is not limited to the corrugated pipe, it is natural that any one can be applied as long as it can absorb mechanical impact.

As described above, according to the embodiment of the present invention, the mechanical impact energy transmitted through the movable side conducting electrode 12 of the vacuum interrupter 200 during the opening and closing operation of the vacuum interrupter is not only the terminal 28 but also the fixed side seal cup ( 42) and absorbed by the corrugated pipe 40 without being transferred to the insulating container 14, the deformation of the insulating container 14 and the fixed-side seal cup 42 is not generated, and cracks are not generated. It is possible to obtain the effect of keeping the vacuum tight.

As described above, according to the present invention, the impact energy transmitted to the fixed side seal cup and the insulation container is absorbed in advance by the shock buffer member for absorbing the impact energy during opening and closing operation of the mechanism part of the vacuum interrupter, thereby preventing deformation and cracking of the vacuum interrupter. It is effective in preventing.

In addition, even if the amount of impact energy transmitted from the breaker mechanical unit increases as the breaking capacity of the vacuum interrupter increases, the mechanical stress transmitted to the fixed side metal seal cup and the ceramic insulated container is remarkably increased because the mechanical shock is absorbed in the corrugated pipe. It is lowered and there exists an effect which improves the reliability about the vacuum tightness of a vacuum circuit breaker, etc.

Claims (4)

An insulating container in which a movable side conducting electrode connected to an insulating rod for transferring mechanical energy, a lower fixed side conducting electrode corresponding to the movable side conducting electrode, and the movable side conducting electrode and a fixed side conducting electrode are inserted through the center thereof; In the vacuum interrupter of the vacuum circuit breaker comprising a movable side and a fixed side seal cup coupled to the movable side conducting electrode and the fixed side conducting electrode and the insulating container to maintain airtightness, And a shock absorbing member is formed between the fixed side conducting electrode and the fixed side seal cup. The method of claim 1, The shock absorbing member is a vacuum interrupter of the vacuum interrupter, characterized in that it comprises a corrugated pipe. The method according to claim 1 or 2, The shock absorbing member is a vacuum interrupter of the vacuum circuit breaker, characterized in that it comprises a corrugated pipe of a metal material. The method according to claim 1 or 2, The shock absorbing member is a vacuum interrupter of a vacuum circuit breaker, characterized in that it comprises a corrugated pipe of rubber material having insulation and heat resistance.