KR101699003B1 - Contact of axial magnetic field type vacuum circuit breaker - Google Patents

Abstract

Field of the Invention [0002] The present invention relates to a contact of a shaft-type vacuum circuit breaker capable of enhancing a flow field of current flowing from an electrode so as to enhance a shaft magnetic field at a current peak and suppressing the generation of eddy current.
The contact of the shaft magnetic field type vacuum circuit breaker according to the present invention,
A contact of a shaft-type vacuum circuit breaker in which a plurality of inward slits continuing inward from an edge to a disc-shaped body are provided continuously at regular intervals,
A first concave surface continuing at regular intervals is provided on the body edge between the inward slits,
The first depressed surface is located between the leading edge of each of the inclined slits provided in the electrode and each of the inwardly directed slits adjacent thereto and induces a current flowing in a diagonal direction along the inclined slit of the electrode in a relatively horizontal direction .

Description

BACKGROUND OF THE INVENTION Field of the Invention [0001] The present invention relates to a contact of an axial magnetic field type vacuum circuit breaker

The present invention relates to a contact point of a shaft-type vacuum circuit breaker, and more particularly, to a contact point of a shaft-type vacuum circuit breaker capable of improving flow of a current flowing from an electrode so as to enhance a shaft magnetic field at a current peak, To the contacts of the shaft-type vacuum breaker.

The vacuum circuit breaker is installed in a high voltage power system of 3.3 kV or more. When a dangerous large current flows into the load system due to a short-circuit accident or the like, the accident current is immediately blocked to protect the power system.

At this time, the vacuum circuit breaker is provided with a vacuum valve (vacuum interrupter) as disclosed in Japanese Laid-Open Patent Publication No. 2002-0085262 (published on November 16, 2002).

As shown in FIG. 6, the vacuum valve 200 provided in the vacuum circuit breaker opens the contact A 'as the electrode 100' facing each other is opened by the operation of the mechanism of the vacuum circuit breaker in the event of occurrence of an accident current, So that the current is interrupted by appropriately extinguishing the arc.

In the vacuum valve, there is a shaft magnetic type vacuum valve.

The axial magnetic field type vacuum valve is designed so that a magnetic field can be formed in the axial direction. By applying an axial magnetic field to the arc generated between the contact points, it is possible to prevent the arc from being concentrated in a large current.

It is preferable that such a shaft magnetic field type vacuum valve maintains the axial magnetic field strongly at the current peak, and it is desirable to keep the axial magnetic field weakly at the current zero point.

At this time, the strengthening and weakening of the axis magnetic field of the vacuum valve may be influenced by the shape of the electrode.

That is, since the current flows from the inside of the circumference to the axial direction in a different direction according to the shape of the electrode when the current flows, the strengthening and weakening of the axis magnetic field can be influenced from the shape of the electrode.

In addition, reinforcement and weakening of the axial magnetic field can be influenced by the shape of the contact with the electrode.

In other words, depending on the shape of the contact point, the degree of the eddy current generated at the contact point is different, and as the eddy current is generated, the reinforcement and weakening of the axial magnetic field adversely affect the reinforcement and weakening of the axial magnetic field. .

On the other hand, in the shaft magnetic field type vacuum valve, the electrode is provided with the inclined slit, and the contact point is provided with the inward slit.

Since the inclined slits are provided in the electrodes of the shaft magnetic field type vacuum valve and the inward slits are provided at the contact points, current flow in the electrodes and the contacts can be interrupted through the inclined slits and the inward slits, so that the axial magnetic field can be strengthened.

However, as shown in FIG. 7, the current flowing in the oblique direction along the inclined slit 110 'of the electrode 100' is sharply lowered toward the contact A ' There is a problem that the effect of reinforcing the axial magnetic field is deteriorated.

The sloped slit 110 'provided in the electrode 100' is strengthened in the axial magnetic field at the current peak as the inclination angle becomes milder.

However, if the inclination angle of the inclined slit 110 'of the electrode 100' is made gentle to reinforce the axial magnetic field at the current peak, as shown in FIG. 8, the inclined slit 110 ' The inner tip of the inward slit 20 'of the contact A' is significantly deviated from the center of the contact A '.

When the inner tip of the inward slit 20 'of the contact A' deviates considerably from the center of the contact A ', the area where the eddy current can be generated (the inner slit 20' The center portion) is enlarged, an eddy current is generated, which hinders strengthening of the axial magnetic field at the current peak.

SUMMARY OF THE INVENTION The present invention has been made in view of the above circumstances, and it is difficult to strengthen the axial magnetic field at the current peak due to the limitation of the inclination angle of the oblique slit provided in the electrode due to the relation with the inward slit provided at the contact And to provide a contact point of a shaft-type vacuum circuit breaker which can solve the problem that has been followed.

In addition, the present invention provides a contact of a shaft-type vacuum circuit breaker which can solve the problem that the eddy current is generated as the eddy current generating area increases toward the center of the contact point toward the center of the contact, The purpose is to provide.

According to an aspect of the present invention, there is provided a contact of a shaft-type vacuum circuit breaker,

A contact of a shaft-type vacuum circuit breaker in which a plurality of inward slits continuing inward from an edge to a disc-shaped body are provided continuously at regular intervals,

A first concave surface continuing at regular intervals is provided on the body edge between the inward slits,

The first depressed surface is located between the leading edge of each of the inclined slits provided in the electrode and each of the inwardly directed slits adjacent thereto and induces a current flowing in a diagonal direction along the inclined slit of the electrode in a relatively horizontal direction .

Here, the body is provided with a protruding portion inside the edge.

And a second concave surface is provided on the inside of the protrusion.

Each of the inward slits is oriented at an equal angle from the body edge toward the center of the body, wherein the inner angle between the outer tip from the inner tip and the center of the body from the outer tip is within 0-30 °.

The contact for a shaft magnetic field vacuum interrupter according to the present invention is provided with a first depressed surface between inward slits provided in the body, and a current flowing in an oblique direction along the inclined slit in the electrode reaches the first depressed surface Since the current flows in the relatively horizontal direction, the current flow can be improved between the electrode and the electrode, thereby enhancing the axial magnetic field at the current peak.

In addition, the contact point for the axial magnetic field vacuum interrupter according to the present invention is improved in the flow of current by the first depressed surface, and the inclination of the slit of the electrode itself does not become gentle. The inside tip of the inward slit, The inclination angle of the inclined slit does not deviate greatly from the center of the body as in the case of the gentle inclination angle of the inclined slit, so that the area where the eddy current can occur is reduced, thereby suppressing the occurrence of eddy currents.

1 is a perspective view showing a structure of a contact for a shaft magnetic field vacuum interrupter according to the present invention;
FIG. 2 is a perspective view of a contact for a shaft magnetic field vacuum interrupter according to an embodiment of the present invention,
FIG. 3 is a perspective view showing a shape in which a second concave surface is provided at a protrusion at a contact point for a shaft magnetic field vacuum interrupter according to the present invention. FIG.
4 is an exemplary view for explaining the enhancement of the axial magnetic field by improving the current flow at the contact point for the axial magnetic field vacuum interrupter according to the present invention
5 is an exemplary diagram for explaining the suppression of the occurrence of eddy current by improving the current flow at the contact point for a shaft magnetic field vacuum interrupter according to the present invention
6 is an exemplary diagram for explaining the structure of a general vacuum valve
7 is an exemplary diagram showing current flow between a contact for a conventional axial field vacuum interrupter and an electrode
8 is an exemplary diagram for explaining generation of an eddy current at a contact point for a conventional axial field vacuum breaker

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

As shown in FIG. 1, a contact A for a shaft magnetic field vacuum interrupter according to the present invention includes a body 10, an inward slit 20, and a first recessed surface 30.

The body 10 is in the form of a disc.

In such a body 10, as shown in FIG. 2, a protruding portion 11 may be provided inside the edge 12.

The protrusion 11 is provided inside the edge 12 of the body 10 so that the protrusion 11 protrudes from the groove formed in the bottom surface of the electrode 100 when the contact A and the electrode 100 are engaged It is possible to prevent the body 10 from flowing on the electrode 100.

At this time, a second recessed surface 11a may be provided on the inner side of the protrusion 11 of the body 10, as shown in FIG.

Since the eddy current generating region is reduced by the area of the second depressed surface 11a by providing the second depressed surface 11a inside the protruding portion 11 of the body 10, eddy current generation is suppressed.

The inward slit 20 extends inwardly from an edge 12 of the body 10. [

Each of the inward slits 20 is oriented at an equal angle from the edge of the body 10 toward the center of the body 10 so that the inner angle between the outer tip from the inner tip and the center of the body 10 from the outer tip thereof is 0-30 Deg.].

Each of the inward slits 20 faces the center of the body 10 at the same angle from the edge of the body 10 and the inner angle between the outer tip and the outer tip of the inner tip is 0-30 deg. The tip of the inward slit 20 extends to the central portion of the body 10, so that the eddy current generating region can be reduced, thereby minimizing the interference of the axial magnetic field enhancement due to the eddy current.

On the other hand, the inward slits 20 are provided in the same number as the number of the slanted slits 110 provided in the electrode 100.

The inward slits 20 are provided in the same number as the number of the slanted slits 110 provided in the electrode 100 so that the current flowing between the slanted slits 110 of the electrode 100 through the inward slits 20 is interrupted .

The first recessed surface (30) is located at the edge of the body (10).

It is preferable that the first concave surface 30 is positioned between the tip end of each of the inclined slits 110 provided in the electrode 100 and the respective inward slits 20 adjacent thereto.

The first recessed surface 30 is located between the tip end of each of the inclined slits 110 provided on the electrode 100 and the respective inward slits 20 adjacent thereto so that the inclined slits The current flowing in the oblique direction along the first concave surface 110 flows in the relatively horizontal direction as it reaches the first concave surface 30, so that the current flow can be improved and the axial magnetic field can be strengthened.

Hereinafter, the reinforcement of the axial magnetic field at the contact (hereinafter, referred to as 'contact') A of the axial magnetic field type vacuum circuit breaker according to the present invention will be described in detail.

In the present invention, the body 10 in contact with the electrode 100 is provided with a first recessed surface 30 in addition to the inward slit 20.

At this time, the first concave surface 30 is located between the tip end of the example of the inclined slit 110 provided in the electrode 100 and the inward slit 20 adjacent thereto.

4, the current flowing in the oblique direction between the inclined slits 110 of the electrode 100 is formed by the first recessed portion 30, And is guided in the lateral direction while flowing to the surface 30 to flow in a relatively horizontal direction.

Thus, the current flowing in the first concave surface 30 flows in the relatively horizontal direction, so that the axial magnetic field can be strengthened at the current peak as compared with the current flowing in the diagonal direction.

In the present invention, since the axial magnetic field strengthening is achieved by improving the flow of current by the first concave surface 30 as described above, the influence of the inclined angle of the oblique slit 110 provided on the electrode 100 Can be relatively free from.

5, each of the inward slits 20 provided in the body 10 is inclined at an equal angle from the edge of the body 10 to the center of the body 10, And the internal angle between the outer tip from the inner tip and the center of the body 10 from the outer tip of the tip is within 0-30 °.

At this time, since the inner tip of the inward slit 20 extends to the central portion of the body 10, the eddy current generation region can be reduced, and eddy current generation can be suppressed.

Therefore, the present invention can prevent the interference of the axial magnetic field enhancement due to the generation of the eddy current.

In the present invention, a second recessed surface 11a is provided inside the protrusion 11 which is inserted into a groove (not shown in the figure) formed on the bottom surface of the electrode 100 and prevents the flow of the body 10.

Since the second concave surface 11a is provided inside the protrusion 11 as described above, the eddy current generation region can be reduced, so that the occurrence of the eddy current can be further suppressed.

As described above, the contact A for a shaft magnetic field vacuum interrupter according to the present invention is such that a current flowing in the oblique direction along the oblique slit 110 in the electrode 100 reaches the first concave surface 30, The current flow can be improved with respect to the electrode 100, so that the axial magnetic field can be strengthened at the current peak.

The contact point A for a shaft magnetic field vacuum interrupter according to the present invention is characterized in that the inner tip of the inward slit 20 provided in the body 10 extends to the center of the body 10 to reduce the eddy current generation region, .

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments.

10: body 11:
11a: second depression surface 12: edge
20, 20 ': inward slit 30: first recessed surface
100, 100 ': electrode 110, 110': slit
A, A ': Contact point P: Example part

Claims (4)

A contact of a shaft-type vacuum circuit breaker in which a plurality of inward slits continuing inward from an edge to a disc-shaped body are provided continuously at regular intervals,
A first concave surface continuing at regular intervals is provided on the body edge between the inward slits,
The first depressed surface is positioned between the tip end of each of the inclined slits provided in the electrode coupled to the body and each of the inwardly directed slits adjacent to the inclined slit so as to induce a current flowing in the oblique direction along the inclined slit of the electrode in the horizontal direction However,
Wherein the body is provided with a protruding portion inside the edge. delete The method according to claim 1,
And a second concave surface is provided on the inside of the protrusion of the body. The method according to claim 1,
Each of the inward slits facing the center of the body at the same angle from the edge of the body, wherein the inner angle between the outer tip from the inner tip and the center of the body from the outer tip is within 0-30 [deg.], .

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