KR20140075418A - Gas insulated switchgear including moving part having short travel distance in fixing part - Google Patents

Abstract

Provided is gas insulated switchgear including a moving part having a short travel distance within a fixing part. The gas insulated switchgear includes the fixing part with a fixing main contact point and a fixing arc contact point; and the moving part with a moving arc contact point facing the fixing part, a contact point rod, a moving main contact point, a connector, and a rod link. While the moving part is inserted into the moving part, the rod link is parallel to the contact point rod in the contact between the fixing main contact point and the moving arc contact point.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a gas insulated switchgear including a movable portion having a short travel distance in a fixed portion,

Embodiments of the present invention relate to a gas insulated switchgear comprising a movable portion having a short travel distance within a fixed portion.

Generally, the gas insulated switchgear includes an operating portion, a fixed portion, and a movable portion. The operating portion is configured to relatively move the movable portion with respect to the fixed portion. The operating portion may allow the movable portion to be inserted into the fixed portion so as to allow the AC high current to flow in order to form the steady current state of the gas insulated switchgear. The operating portion can isolate the movable portion from the fixed portion in response to the state of the fault current of the gas insulated switchgear, thereby shutting off the AC high current.

However, when the driving force of the operating portion is dispersed at the movable portion at the time of contact between the fixed portion and the movable portion, the operating portion can forcibly transmit the driving force to the movable portion to forcibly fit the movable portion to the fixed portion. Hereinafter, a gas insulated switchgear according to the prior art will be described with reference to Figs. 1 and 2. Fig.

FIG. 1 is a schematic view for explaining the operation of a gas insulated switchgear according to the prior art, and FIG. 2 is a schematic view showing a contact point of a fixed portion and a movable portion in the gas insulated switchgear of FIG.

1 and 2, the gas insulated switchgear 60 has a fixed portion A, a movable portion B, and an actuator (not shown in the figure). The fixing portion (A) has a fixed main contact (4) and a fixed arc contact (8). The fixed main contact (4) surrounds the fixed arc contact (8). The movable portion B has a movable main contact 13, a rod 16, a movable arc contact 19, a splice 25, a link 33 and a lever 40.

The movable main contact 13 surrounds the rod 16. The rod 16, the movable arc contact 19 and the splice 25 are fixed to each other. The link 33 is coupled to rotate about the connector 25 via one end pin 39. The lever 40 is rotatably coupled to the pin 36 at the other end of the link 33 and rotates around the fixed gear 50.

In this case, in order to form the steady current state of the gas insulated switchgear 60, the movable portion B is moved in the first direction D1 toward the fixed portion A using the driving force of the manipulating device .

The lever 40 can be moved along the traces 40A and 40B toward the fixed main contact 4 or stationary arc contact 8 while the lever 40 is rotated to the periphery of the fixed gear 40 have. In addition, the link 33 can continue to move along the trajectories 33A, 33B in conjunction with the rotation of the lever 40. [0053] 2, a contact line L2 connecting the centers of the pin 36 and the fixed gear 50 at the other end of the link 40 at the contact time of the fixed main contact 4 and the movable arc contact 19, As shown in FIG. 2, with respect to a line connecting the centers of the fins 39 and 36 of the one end and the other end of the link 33. As shown in FIG.

The lever 40 can not sufficiently transfer the driving force concentrated in the first direction D1 to the link 33 at the contact time of the fixed main contact 4 and the movable arc contact 19. This is because the driving force of the lever 40 at the contact time of the fixed main contact 4 and the movable arc contact 19 causes the vector force of the line connecting the centers of the application line L2 and the fins 39, And is transmitted to the link 33 in a distributed manner.

Due to a structural problem with the link 33 and the connection of the lever 40, the lever 40 is connected to the rod 16, the movable arc contact 19 and the splice 25 via the link 33, Thereby forcibly transmitting the driving force. The movable arc contact 19 can be fitted to the fixed main contact 4 in response to the driving force of the actuator and can move a long distance along the movable arc contact 8.

That is, when checking the movement distance of the movable arc contact 19 in the fixed main contactor 4 by using the traces 40A and 40B of the lever 40, the lever 40 is fixed to the fixed main contact 4 1 and the maximum rotation angle [theta] 2 to the periphery of the action line L2 at the contact point of the movable contactor 19 and the contact point of the movable arc contact 19. [ 1 corresponds to a first travel distance of the lever 40 that moves away from the line of action L2 and approaches the fixed arc contact 8 closest to it.

That is, the first movement distance is a distance between the action lines L2 and L3. 2 corresponds to the second travel distance of the lever 40 moving away from the line of action L2 and furthest away from the fixed arc contact 8. That is, the second movement distance is the distance between the action lines L1 and L2. The sum of the first and second travel distances is 95.1 mm. In this case, the minimum rotation angle [theta] 1 has the same magnitude as the maximum rotation angle [theta] 2.

The operating portion can move the movable portion B to the fixed portion A when the driving force of the operating portion is dispersed in the movable portion B at the contact time of the fixed main contact 4 and the movable arc contact 19, The driving force is forcibly transmitted to the movable portion B. Therefore, the movable portion B can generate a large number of particles separated from the components due to unreasonable contact between the components. In addition, the operating portion must be large in overall size in order to increase the driving capacity for the movable portion B.

SUMMARY OF THE INVENTION A problem to be solved by the present invention is to provide a gas insulated switchgear comprising a movable portion having a short moving distance in a fixed portion suitable for shortening the moving distance of the movable portion in the fixed portion so as to form a steady current state have.

Other problems to be solved by the present invention are not limited to the above-mentioned problems, and other problems not mentioned here will be fully understood by those skilled in the art from the following description.

A gas insulated switchgear including a movable portion having a short moving distance in a fixing portion according to embodiments of the present invention includes: a fixing portion including a fixed main contact and a fixed arc contact; And a movable portion including a movable arc contact, a contact rod, a movable main contact, a connector and a rod link while facing the fixed portion. The fixed main contact surrounds the fixed arc contact. The movable arc contact and the contact rod are arranged in order with respect to the fixed arc contact and are cylindrical and fixed relative to each other. The movable main contact surrounds the contact rod. The connector is surrounded by the contact rod on the opposite side of the movable arc contact and fixed to the contact rod. Wherein the load link is coupled to the connector through one end and rotates relative to the connector to move the movable arc contact, the contact rod, and the connector through the movable main contact, At the point of contact of the movable arc contact, it is parallel to the contact rod.

The gas insulated switchgear further includes a rotation lever that is rotatably coupled to the other end of the load link. At the contact point of the fixed main contact and the movable arc contact, the fixed arc contact is located on the same horizontal line together with the one end and the other end of the load link.

Wherein the gas insulated switchgear includes: a rotation lever rotatably coupled to the other end of the load link; And a fixed gear surrounded by the rotating lever on the opposite side of the load link to induce rotation of the rotating lever. The operating line connecting the fixed gear and the other end of the load link is perpendicular to the horizontal line connecting the one end and the other end of the load link at the contact time of the fixed main contact and the movable arc contact.

Wherein the gas insulated switchgear includes: a rotation lever rotatably coupled to the other end of the load link; And a fixed gear surrounded by the rotating lever on the opposite side of the load link to induce rotation of the rotating lever. A contact line connecting the fixed gear and the other end of the load link at a point of time of contact between the fixed main contact and the movable arc contact is connected to the fixed arc contact and a horizontal line connecting the one end of the load link and the other end .

Wherein the gas insulated switchgear includes: a rotation lever rotatably coupled to the other end of the load link; And a fixed gear surrounded by the rotating lever on the opposite side of the load link to induce rotation of the rotating lever. The rotation lever is rotated between a minimum rotation angle and a maximum rotation angle to the periphery of a line of engagement between the fixed gear and the other end of the load link at the contact time of the fixed main contact and the movable arc contact. The minimum rotation angle corresponds to the movement distance of the rotation lever that moves away from the action line and is closest to the fixed arc contact. The maximum rotation angle corresponds to a movement distance of the rotation lever moving away from the action line and furthest from the fixed arc contact. The maximum rotation angle has a magnitude larger than the minimum rotation angle.

As described above, the gas insulated switchgear including the movable portion having the short travel distance in the stationary portion according to the embodiments of the present invention has the contact load parallel to each other at the contact time of the fixed main contact and the movable arc contact, And the driving force of the manipulating device can be fully transmitted to the movable portion with the load link.

 The gas insulated switchgear can minimize the particles generated from the components of the movable part by fully transferring the driving force of the actuator to the movable part.

The gas insulated switchgear can transfer the driving force of the actuating device to the movable portion in a perfect manner to shorten the moving distance of the movable portion in the fixed portion.

The gas insulated switchgear can shorten the moving distance of the movable portion in the fixed portion and reduce the driving required amount of the actuator.

The gas insulated switchgear can reduce the driving amount of the operation device and can pursue miniaturization.

1 is a schematic view for explaining the operation of a gas insulated switchgear according to the prior art.
Fig. 2 is a schematic view showing the contact points of the fixed portion and the movable portion in the gas insulated switchgear of Fig. 1;
3 is a schematic view illustrating the operation of the gas insulated switchgear according to the present invention.
Fig. 4 is a schematic view showing the contact points of the fixed portion and the movable portion in the gas insulated switchgear of Fig. 3;

First, a gas insulated switchgear including a movable portion having a short travel distance in a fixing portion according to embodiments of the present invention will be described in detail with reference to FIGS. 3 and 4. FIG.

FIG. 3 is a schematic view illustrating the operation of the gas insulated switchgear according to the present invention, and FIG. 4 is a schematic view showing a contact point of the fixed portion and the movable portion in the gas insulated switchgear of FIG.

3, the gas insulated switchgear 160 according to the embodiments of the present invention includes a fixing portion A1, a movable portion B1, and an actuator (not shown in the figure). The fixing portion A1 includes a fixed main contact 104 and a fixed arc contact 108. [ The fixed main contact 104 surrounds the fixed arc contact 108. The fixed arc contact 108 has a long rod shape. The movable portion B1 faces the fixing portion A1.

The movable portion B1 includes a movable main contact 113, a contact rod 116, a movable arc contact 119, a connector 125, a load link 133 and a rotation lever 140. [ The movable main contact 113 may surround the contact rod 116. The contact rod 116 is formed in a cylindrical shape. The movable arc contact 119 extends from the contact rod 116 toward the fixed main contact 104 or fixed arc contact 108. The movable arc contact 119 is fixed to the contact rod 116.

The connector 125 is surrounded by a contact rod 116 on the opposite side of the movable arc contact 119. The connector 125 is fixed to the contact rod 116. The load link 133 is coupled to the connector 125 through a first pin 139 at one end. The load link 133 rotates with respect to the connector 125 and moves the contact rod 116, the movable arc contact 119 and the connector 125 through the movable main contact 113.

The rotation lever 140 is rotationally coupled to the second pin 136 of the other end of the load link 133. The rotation lever 140 surrounds the fixed gear 150 located on the opposite side of the load link 133 and rotates around the fixed gear 150. That is, the fixed gear 150 induces the rotation of the rotary lever 140. The manipulator can transmit the driving force to the movable portion B1 to sandwich the movable portion B1 in the fixed portion A1.

More specifically, the actuator transmits a driving force to the rotary lever 140 to move the contact rod 116, the movable arc contact 119 and the connector 125 in the second direction D2. Through this, the movable arc contact 119 is fitted to the fixed main contact 104. In addition, the fixed arc contact 108 is fitted to the movable arc tangent 119.

In this case, the rotary lever 140 can be rotated around the fixed gear 150 using the driving force of the manipulating device. While the rotation lever 140 is rotating, the rotation lever 140 generates traces 140A and 140B to rotate the fixed gear 150 and the second pin 136 of the other end of the load link 133 The minimum rotation angle 3 and the maximum rotation angle 4 can be formed using the connecting lines L4, L5, and L6.

That is, the rotation lever 140 rotates the fixed gear 150 and the second pin 136 of the other end of the load link 133 at the contact time of the fixed main contact 104 and the movable arc contact 119 of FIG. 3 between the minimum rotation angle 3 and the maximum rotation angle 4, as shown in Fig. The minimum rotation angle 3 corresponds to the first travel distance of the rotary lever 140 that moves away from the line of action L5 and approaches the fixed arc contact 108 closest.

The maximum rotation angle 4 corresponds to the second movement distance of the rotation lever 140 moving away from the action line L5 and furthest away from the fixed arc contact 108. [ The maximum rotation angle [theta] 4 is larger than the minimum rotation angle [theta] 3. On the other hand, the load link 133 is parallel to the contact rod 116 at the contact time of the fixed main contact 104 and the movable arc contact 119 as shown in FIG.

The centers of the first and second pins 139 and 136 at one end and the other end of the load link 133 are connected to the fixed arc contact 108 (108) at the contact time of the fixed main contact 104 and the movable arc contact 119, As shown in FIG. 4, on the same horizontal line C2. The operating line L5 connecting the centers of the fixed gear 150 and the second pin 136 of the other end of the load link 133 at the contact time of the fixed main contact 104 and the movable arc contact 119 And perpendicular to the horizontal line C connecting the centers of the first and second pins 139 and 136 at one end and the other end of the load link 133 as shown in Fig.

The operating line L5 connecting the centers of the fixed gear 150 and the second pin 136 of the other end of the load link 133 at the contact time of the fixed main contact 104 and the movable arc contact 119 The fixed arc contact 108 and the horizontal line C connecting the centers of the first and second pins 139 and 136 at one end and the other end of the load link 133 as shown in Fig.

Due to the coupling structure between the load link and the rotary lever, the sum of the first and second travel distances is 85.8 mm. The sum of the first and second travel distances is small compared to the prior art. This is because the coupling structure of the load link 133 and the rotary lever 140 is such that at the point of contact between the fixed main contact 104 and the movable arc contact 119 the action line L5 and the horizontal line C2 ).

That is, the rotation lever 140 can transmit the driving force of the manipulator to the load link 133 without dispersion of force unlike the prior art.

While the present invention has been described in connection with what is presently considered to be practical exemplary embodiments, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, It will be understood. It is therefore to be understood that the above-described embodiments are illustrative in all aspects and not restrictive.

104; Fixed main contacts, 108; Fixed arc contact,
113; Active arc main contacts, 116; Contact load
119; Movable arc contacts, 125; coupler
133, 133A, 133B; Load link, 136, 139; pin
140, 140A, 140B; Rotation lever, 150; Fixed gear
160; Gas insulated switchgear, A1; Stator
B1; Mover, D2; direction
L4, L5, L6; Acting line,? 3,? 4; Rotation angle

Claims (5)

A fixed portion including a fixed main contact and a fixed arc contact; And
And a movable portion including a movable arc contact, a contact rod, a movable main contact, a connector and a rod link while facing the fixed portion,
The fixed main contact surrounds the fixed arc contact,
The movable arc contact and the contact rod are arranged in order with respect to the fixed arc contact and are cylindrical and fixed relative to each other,
Wherein the movable main contact surrounds the contact rod,
The connector is surrounded by the contact rod on the opposite side of the movable arc contact and is fixed to the contact rod,
Wherein the load link is coupled to the connector through one end, and rotates relative to the connector to move the movable arc contact, the contact rod, and the connector through the movable main contact, And a movable portion having a short travel distance in a stationary portion parallel to the contact rod at a contact point of the movable arc contact. The method according to claim 1,
And a rotation lever rotatably coupled to the other end of the load link,
The contact point of the fixed main contact and the movable arc contact includes a movable portion having a short travel distance within the fixed portion located on the same horizontal line with the one end and the other end of the load link Gas insulated switchgear. The method according to claim 1,
A rotating lever rotatably coupled to the other end of the load link; And
Further comprising a fixed gear surrounded by the rotating lever on the opposite side of the load link to induce rotation of the rotating lever,
Wherein a line of engagement between the fixed gear and the other end of the rod link at a point of time of contact between the fixed main contact and the movable arc contact is formed in a fixed portion perpendicular to a horizontal line connecting the one end and the other end of the rod link And a movable part having a short travel distance in the gas insulated switchgear. The method according to claim 1,
A rotating lever rotatably coupled to the other end of the load link; And
Further comprising a fixed gear surrounded by the rotating lever on the opposite side of the load link to induce rotation of the rotating lever,
A contact line connecting the fixed gear and the other end of the load link at a point of time of contact between the fixed main contact and the movable arc contact is connected to the fixed arc contact and a horizontal line connecting the one end of the load link and the other end And a movable portion having a short moving distance within the fixed portion which is perpendicular to the fixed portion. The method according to claim 1,
A rotating lever rotatably coupled to the other end of the load link; And
Further comprising a fixed gear surrounded by the rotating lever on the opposite side of the load link to induce rotation of the rotating lever,
The rotation lever is rotated between a minimum rotation angle and a maximum rotation angle to the periphery of a line of engagement between the fixed gear and the other end of the load link at the contact time of the fixed main contact and the movable arc contact,
Said minimum rotation angle corresponding to a travel distance of said rotary lever moving closest to said stationary arc contact,
The maximum rotation angle corresponding to a travel distance of the rotary lever moving away from the action line and furthest from the fixed arc contact, and
Wherein the maximum rotation angle includes a movable portion having a short movement distance within a fixed portion having a size larger than the minimum rotation angle.

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