KR20080102931A - Vacuum interrupter - Google Patents

Abstract

A vacuum interrupter including a metal member for fixing and a coupling member is provided to reduce a manufacturing cost by absorbing a dimension unbalanced in a production process of an arc shield. A vacuum interrupter comprises the followings: a vacuum container(30) mounting a first insulating container and a second insulating container of a cylinder type; a pair of electrodes formed in the vacuum container; a arc shield(10) of a pipe-shaped which surrounds both electrodes; a coupling member(9) of a ring shape which connects the first insulating container and the second insulating container; and a metal member for fixing(11) of the arc shield.

Description

Vacuum Interrupter {VACUUM INTERRUPTER}

The present invention relates to a vacuum interrupter provided with an arc shield surrounding a foldable pair of electrodes formed in a vacuum vessel.

The vacuum interrupter opens the electrode on the movable side, which was in contact with the fixed electrode at the time of interruption of the current, from the fixed side electrode to cut off the current, but an arc occurs at the folding point of both electrodes at the time of interruption of the current. With this, metal vapor is generated, but if the metal vapor adheres to the inner surface of the insulated container constituting the vacuum container, the insulating property is deteriorated. Therefore, in a vacuum interrupter, the arc is used to surround the vicinity of the folding point of the positive electrode. The shield is disposed, and the arc shield prevents metal vapor from adhering to the inner surface of the insulated container. For example, as shown in FIG. 5 of patent document 1, the arc shield forms the emboss part in the outer diameter side, and is fixing by the support metal component and soldering.

[Patent Document 1] Japanese Patent Application Laid-Open No. 2000-294089

Conventional vacuum interrupters must be produced by cutting or pressing the embossed portion on the outer diameter side of the arc shield. When the arc shield having a structure in which both ends of the arc shield are tightened on the inner diameter side is manufactured by pressing, the dimensional tolerance of the outermost portion of the arc shield is increased, and adding an embossed part becomes expensive, and also the dimensional tolerance of the outer diameter of the embossed part Gets bigger In addition, when the embossed part is manufactured by cutting, the dimensional tolerance of the outermost part of the arc shield is large, so that the arc shield cannot be processed without increasing the thickness of the arc shield. .

When the structure which absorbs the dimension tolerance of the outer diameter part of an emboss part to a support metal part is formed, the space for constructing an absorption structure between a cylindrical insulation container inner diameter and an arc shield outer diameter is needed. The outer diameter of the vacuum interrupter depends on the electrode diameter for breaking the fault current, the clearance between the electrode and the arc shield for the breakdown voltage performance, the dimension between the arc shield and the insulated vessel for fixing the arc shield, and the thickness of the insulated vessel. Is determined by. When the structure which absorbs a dimensional tolerance is formed in a support metal part, the outer diameter of a vacuum interrupter becomes large.

The present invention proposes a vacuum interrupter which solves the above problem.

The vacuum interrupter according to the present invention includes a vacuum container configured by combining cylindrical first and second insulated containers, a pair of collapsible electrodes housed in the vacuum container, and a cylindrical arc formed by surrounding these two electrodes. In a vacuum interrupter provided with a shield, the first insulated container and the second insulated container are coupled to each other by a ring-shaped sealing member, and the arc shield is fixed to the metal shield for fixing the arc shield by surrounding the outer circumference thereof. The arc shield is supported and fixed to the sealing member by aligning and soldering the fixing metal band to the sealing member.

The fixing metal stand and the sealing member are fitted to each other so that the whole or a part of the tip of the fixing metal stand touches the side surface of the sealing member.

The arc shield and the fixing metal stand are fixed by welding.

In addition, the fixing metal band is characterized in that a gap is formed in a part of the ring shape.

According to the vacuum interrupter of the present invention, since it is possible to support and fix the arc shield that can absorb the dimensional imbalance in the manufacturing process of the arc shield, it is possible to use an inexpensive one manufactured by press working on the arc shield, Fixed metal stand can be manufactured by press working at low cost. Therefore, the cost of the vacuum interrupter can be reduced.

In addition, the fixing method of the arc shield is simplified, and the space dimension between the arc shield and the fixing metal stand and the insulated container can be minimized, thereby minimizing the outer diameter of the insulated container, that is, miniaturizing the vacuum interrupter.

Embodiment 1.

1 is a cross-sectional view showing the configuration of a vacuum interrupter according to the first embodiment. This vacuum interrupter has cylindrical first and second insulating containers 1a and 1b made of alumina-ceramics and the like, and these first and second insulating containers 1a and 1b are combined to form a cylindrical shape. The vacuum container 30 of this is comprised. One end of the first insulating container 1a is hermetically closed by the fixed side end plate 2. One end of the second insulated container 1b is closed by the movable side end plate 3. These fixed side and movable side end plates 2 and 3 are coaxially attached to the end faces of the insulating containers 1a and 1b by soldering, respectively.

In the vacuum container 30 formed from the insulating containers 1a and 1b, the fixed electrode 4 and the movable electrode 7 are formed to face each other, and the fixed electrode 5 has a fixed electrode 5 at its tip. The movable electrode 6 is soldered to the movable electrode 7 at its tip. The fixed electrode bar 4 is disposed in the vacuum vessel 20 through the fixed side end plate 2 and is hermetically soldered to the fixed side end plate 2. On the other hand, the movable electrode 7 is inserted into the vacuum container 30 through the opening 3a provided in the movable side end plate 3, for example, is made in a pleated shape with thin stainless steel, and is vacuum-tight. The movable side electrode bar 7 is attached to the movable side end plate 3 via bellows 8 arranged to be movable while maintaining. By this bellows 8, the movable electrode 7 moves in the axial direction, and the fixed electrode 5 and the movable electrode 6 can be folded while maintaining the vacuum tightness of the vacuum container 30. As shown in FIG.

The cylindrical 1st and 2nd insulated containers 1a and 1b are joined by the sealing member 9 arrange | positioned between them by soldering. The sealing member 9 has the ring shape shown to Fig.5 (a), (b), is inserted between the 1st, 2nd insulated containers 1a, 1b, and joins two containers, The dimension is an insulated container. It slightly protrudes toward the inner diameter side beyond the thickness of (1a, 1b). The sealing member 9 is made of copper or copper alloy, which is a soft metal, for reducing the residual stress of the solder joints with the insulating containers 1a and 1b. Alternatively, it may be made of a coba or iron-nickel alloy having a high thermal expansion coefficient close to the insulating containers 1a and 1b. An arc shield 10 is formed in the space between the positive electrodes 5 and 6 and the insulating containers 1a and 1b so as to cover the vicinity of the fold point of the fixed electrode 5 and the movable electrode 6. The arc shield 10 has an insulating metal between the fixed side and the movable wind by attaching metal vapor of the electrode by the arc generated between the fixed electrode 5 and the movable electrode 6 to the inner surfaces of the insulating containers 1a and 1b. This is to prevent deterioration of the characteristics.

The arc shield 10 has fastening parts 10a and 10b of the shape by which both ends were fastened to the inner diameter side. This has the effect of suppressing the amount of metal vapor of the electrode caused by the arc adhering to the inner surfaces of the insulating containers 1a and 1b, but in the case of manufacturing the arc shield 10 having the tightening portions 10a and 10b by press working. The dimensional tolerance of the arc shield outermost diameter becomes larger than ± 0.5 mm.

A ring-shaped fixing metal band 11 having a thickness of about 0.5 mm to 1.0 mm is fixed to the outer circumference of the arc shield 10. This is to support and fix the arc shield 10, as will be described later, as shown in the front view (a) and plan view (b) of Figure 3 by expanding its shape, the thickness of 0.5 ~ 1mm ) Plate is shaped into a ring shape, and a gap portion 11a is provided in a portion of the ring shape. One of the fixing methods of the arc shield 10 and the fixing metal stand 11 is a solder joint. For example, when the soldering material used for the other solder joint part of a vacuum interrupter is a silver-copper soldering material, there exists a method of solder-bonding using a nickel-copper soldering material with a higher melting point. When the final sealing soldering of the vacuum interrupter is carried out in the vacuum furnace, the solder joints of the arc shield 10 and the fixing metal stand 11 will be re-dissolved if the brazing material having the same melting point is used. It is because there exists a possibility that a joining may shift by this. In the second method of fixing, when both the arc shield 10 and the fixing metal stand 11 are made of stainless steel, welding is performed, in particular, welding by spot welding is simple and inexpensive. Can be.

It is sectional drawing which expands and shows the structure of the principal part of Embodiment 1 which concerns on this invention. The fixing metal stand 11 fixed to the arc shield 10 is arrange | positioned in engagement with the sealing member 9 arrange | positioned between the 1st, 2nd insulated containers 1a, 1b. Since the arc shield 10 and the sealing member 9 cannot be soldered directly due to the dimensional imbalance of the arc shield 10, the fixing metal stand 11 is disposed between the arc shield 10 and the sealing member 9. The fixing metal stand 11 and the sealing member 9 are bonded together. As for the joining, one side end surface of the fixing metal stand 11 contacts the side end surface of the sealing member 9, and is soldered together. Since the fixing metal stand 11 has a thickness of 0.5-1 mm, by changing the overlapping state of the side end surface of the fixing metal stand 11 and the side end surface of the sealing member 9 in this range, an arc The dimensional imbalance of the shield 10 can be absorbed. However, depending on the size of the dimensional imbalance of the arc shield 10, the sealing member 9 may not be engaged with the fixing metal stand 11 in all directions, and in that case, only the part which is engaged is solder-bonded. do.

4 is an enlarged cross-sectional view showing a fixing example of the arc shield 10 and the fixing metal stand 11 according to the first embodiment of the present invention. Only the arc shield 10 and the fixing metal stand 11 in the cross section of the X-X part of FIG. 1 are shown. The fixing metal stand 11 is fixed around the arc shield 10. In this example, both the arc shield 10 and the fixing metal stand 11 are made of stainless steel, and are fixed by spot welding, and the welding part 20 has five places. The number of welds should just be three or more places from the balance of the expanded point to the outer side of the fixing metal stand 11, and the number of the required fixing strengths of the fixing metal stand 11 and the arc shield 10 is obtained. In view of the above, in view of the workability, the expanded portion outside the fixing metal stand 11 may not be locally formed. Since the maximum external shape in the state in which the fixing metal stand 11 was fixed to the arc shield 10 needs to be less than the inner diameter of the 1st insulated container 1a, spot welding is performed, pressing in jig. The jig allows the fastening metal stand 11 to fit within the maximum allowable contour. Since the thickness of the fixing metal stand 11 is 0.5 mm to 1 mm, which is relatively thin and elastic, the portion between the weld portions 20 is expanded to the outer diameter side during spot welding as shown in FIG. 4.

By using this swollen portion, it is possible to absorb an imbalance in the outermost dimension of the arc shield 10, an imbalance in the inner diameter of the sealing member 9, and an unbalance in the thickness of the fixing metal band 11. This is considered in the fixing strength of the fixing metal stand 11 and the sealing member 9 which withstands the repeated impact to the arc shield 10 which arises at the time of electrode operation, The fixing metal stand 11 and the sealing member 9 are considered. This is because it is not necessary to solder the wires in all directions. Even when the thickness of the fixing metal stand 11 is thin, the arc shield 10 completely follows the fixing metal stand 11 in the case of the maximum outer diameter so that the gap 11a becomes almost Omm. By setting, the arc shield 10 can be made to engage the fixing metal stand 11 with the sealing member 9 at the time of minimum outer diameter dimension.

According to the said structure, the arc shield 10 of the structure which has the clamping parts 10a and 10b which clamped both ends to the inner diameter side can use the cheap thing produced by the press process which becomes large in size imbalance, and the metal stand for fixing (11) is also simple in structure and can be manufactured by press working at low cost. Therefore, the cost can be reduced as a vacuum interrupter.

Moreover, since the fixing method of the arc shield 10 is simplified and the space dimension between the arc shield 10 and the fixing metal stand 11 and the insulating containers 1a and 1b can be minimized, the outer diameter of the insulating container is reduced. Minimization of the dimensions, ie miniaturization of the vacuum interrupter is possible.

BRIEF DESCRIPTION OF THE DRAWINGS It is sectional drawing which shows the vacuum interrupter of Embodiment 1 of this invention.

2 is an enlarged cross-sectional view showing the main part of the first embodiment.

3 is a front view (a) and a plan view (b) showing an enlarged view of the fixing metal band according to the first embodiment.

4 is a cross-sectional view showing an example of fixing the arc shield and the fixing metal stand according to the first embodiment.

FIG. 5: is a front view (a) and top view (b) which expand and show the sealing member of Embodiment 1. FIG.

<Description of the code>

1a first insulated container,

1b second insulated container,

2 fixed side veneer,

Three operation side veneer,

3a opening,

4 fixed electrodes,

5 fixed electrodes,

6 movable electrode,

7 movable electrode,

8 bellows,

9 sealing member,

10 arc shield,

10a inner side clamp of the arc shield,

Inner diaphragm of 10b arc shield,

11 fixing stand,

11a gap,

20 welds,

30 sealed containers.

Claims (4)

A vacuum container constructed by combining cylindrical first and second insulating containers, a pair of collapsible electrodes housed in the vacuum container, and a cylindrical arc shield formed around the two electrodes. In a vacuum interrupter having a), the first insulating container and the second insulating container are coupled through a ring-shaped sealing member, and the arc shield is surrounded by an outer circumference of the arc A vacuum interrupter, wherein said arc shield is supported on and fixed to said sealing member by fixing a shielding metal band of said shield, and soldering by fitting said fixing metal band to said sealing member. The method according to claim 1, And said fixing metal stand and said sealing member are engaged so that all or a part of one end of said fixing metal stand touches the side surface of said sealing member. The method according to claim 1, And said fixing metal stand is fixed to said arc shield by welding. The method according to claim 1, The fixing metal band is a vacuum interrupter, characterized in that a gap is formed in a portion of the ring shape.

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