KR101690130B1 - Gas insulated switchgear - Google Patents

Abstract

One embodiment of the gas insulated switchgear according to the present invention comprises: a first movable body; A first contact part movably provided on the first movable part body; A first rod for moving the first contact part with respect to the first movable part body; A second movable body facing the first movable body; A second contact part movably provided in the second movable part body and capable of contacting and separating from the first contact part; A link portion for generating movement of the second contact portion with respect to the fixed side support; And an induction unit for inducing a linear motion of the second contact part.

Description

[0001] GAS INSULATED SWITCHGEAR [0002]

The present invention relates to a gas insulated switchgear, and more particularly, it relates to a gas insulated switchgear which is capable of sufficiently securing an inter-pole distance to an arc contact of an ultra-high voltage cutoff portion in a small space and clearly forming a contact path, thereby reducing frictional force and increasing durability To a gas insulated switchgear.

[0002] In recent substations, gas-insulated switchgears (GIS) using hexafluorosulfur gas (SF6), which has a high insulation property, are widely employed among the opening and closing mechanisms constituting the high-voltage substation.

Gas Insulated Switchgear is an electric power equipment used for switching, grounding, branching and monitoring of high-voltage transformers of several thousand volts to tens of thousands of volts in power transmission, substation and large-scale power distribution system. It is a switchgear in which an opening and closing device is housed in a tank filled with insulating gas such as sulfur hexafluoride (SF6) for electrical insulation between the arc of generated arc and the pole of alternating current (POLE). Accordingly, it is possible to protect the power system and the power equipment by safely eliminating the breaking current generated in the accident and maintaining the insulation performance even in the transient recovery voltage generated in the gap.

The breaker of a conventional gas insulated switchgear is divided into two parts, a movable side and a fixed side. On the movable side, there are provided a first contact, a nozzle and a cylinder connected to the rod, and a second contact is provided on the fixed side. Here, a compression chamber is provided in the cylinder, and an insulated gas is filled in the compression chamber.

In the gas insulated switchgear, the first contact and the second contact are in contact with each other. However, when interrupting, the first contact is released from the second contact in conjunction with the movement of the rod. In addition, the cylinder is moved in conjunction with the movement of the rod, and the insulated gas filled in the compression chamber is compressed, and the compressed insulated gas is injected through the nozzle into the first contact and the second contact to the release point, The arc is called.

Recently, in order to improve the breaking performance of such a gas insulated switchgear, the second contact of the stationary side also performs a relative movement in a direction away from the first contact, thereby improving the separation speed between the contacts and increasing the distance between the contacts Technology is being used.

Fig. 1 shows a blocking portion of the gas insulated switchgear device in which the second contact is also moved so that the contact can move in both directions. Referring to FIG. 1, the blocking portion of the gas insulated switchgear includes a first movable portion having a first contact located on the left side of FIG. 1 and a second movable portion having a second contact positioned on the right side.

The first movable part is provided with a cylinder (11) movable inside the hollow body (10). A nozzle 12 is provided at an end of the cylinder, and a first contact 13 is provided adjacent to the nozzle. The cylinder 11, the nozzle 12 and the first contact 13 are connected to the first rod 14 extending to the rear side of the body 10 and are moved integrally with respect to the body 10.

A compression chamber (15) is formed in the cylinder (11), and an insulated gas is filled in the compression chamber (15). The compression chamber is reduced in volume by the movement of the cylinder interlocked with the first rod, and the insulated gas inside can be compressed. The compressed insulating gas is injected toward the first contact 13 side through a nozzle communicated with the compression chamber.

The second movable part has a hollow body (20) at a position facing the first movable part. A second contact (21) is provided in the body (20). However, the second contact 21 is not completely fixed to the body but can be moved a predetermined distance.

Meanwhile, the body 20 of the second movable part is provided with a second rod 22 which is connected to the nozzle 12 and can be moved integrally with the first rod of the first movable part. The second rod 22 is movably provided with respect to the body 20 of the second movable part, and is moved relative to the body of the second movable part by interlocking with the first rod.

A protruding connection pin 22a protrudes from the second rod 22 and a rotation link 23 is connected to the protruded connection pin 22a. The rotary link 23 can rotate around a rotary shaft 23a fixed to the second movable body 20. [ A hook 23b is formed at one end of the rotary link 23 and a connection link 24 connected to the end 21a of the second contact 21 is rotatably connected to the other end. The connecting pin 23a is inserted into the hook 23b to connect the second rod and the rotating link.

The bi-directionally movable gas insulated switchgear of Fig. 1 operates as follows. In the gas-insulated switchgear in the steady state, the second contact (21) and the first contact (13) are in contact with each other. Here, when the abnormal state is caused and the fault current is cut off, the first rod 14 is moved in the direction of the arrow.

The cylinder 11, the first contact 13, the nozzle, and the like are integrally moved by the movement of the first rod 14 in the direction of the arrow. Here, the volume of the compression chamber (15) is reduced by the movement of the cylinder (11), and the insulated gas inside is compressed. The compressed insulating gas is injected toward the first contact (13) and the second contact (21) through a nozzle (12) communicated with the compression chamber.

Meanwhile, the second rod 22 is also moved in the direction of the arrow to the left in FIG. 1 in conjunction with the movement of the first rod 14, and the second contact 21 is also moved in the direction toward the right side of FIG. 1 do.

More specifically, the rotary link 25 is rotated about the rotary shaft 23a by the hook 25b, which is linked to the nozzle and moves in unison with the movement of the second rod 22 and is in contact with the connection pin 22a And is rotated clockwise.

The connection link 24 is moved in conjunction with the rotation of the rotary link 25 and the second contact 21 is linearly moved in the right direction of FIG. That is, the rotary motion of the rotary link 25 is converted to the linear motion of the second contact 21 by the connection link 24.

FIG. 1 shows the final blocking state. The first contact 13 is moved to the left in Fig. 1 by the movement of the first rod 14 and the second contact 21 is moved to the right in Fig. 1 by the rotation of the rotation link, 21 are completely separated from the first contact 13 and spaced apart from each other.

In this case, an arc is generated when the contacts are disconnected, and when the current is interrupted, an excessive recovery voltage is generated between the second contact and the first contact. This transient recovery voltage can break the insulation and reduce the blocking performance. Therefore, securing a sufficient gap between the second contact and the first contact at the time of breaking is a technical problem that is important for improving the breaking performance of the gas insulated switchgear.

However, in the case of the conventional gas insulated switchgear using contact movement in both directions, there is a problem that the size of the gas insulated switchgear increases in order to sufficiently secure the distance between the contacts or the stroke of the contact. Further, since the rotary link is used, there is a problem that the durability of the link for converting the linear motion of the second contact is low. In addition, since the rotary motion must be converted to linear motion, there is a problem that the linear alignment is disturbed when the second contact is moved.

SUMMARY OF THE INVENTION The present invention has been made in order to solve the above problems of the prior art, and it is an object of the present invention to provide a structure in which the gap between the contacts is further increased in order to prevent insulation breakdown due to an arc, And an object thereof is to provide a gas insulated switchgear of the present invention.

In addition, the linear motion of the second contact is generated by converting the rotational motion into the linear motion, and the second contact is induced to perform the linear alignment motion, thereby preventing the durability from deteriorating and improving the blocking performance, And to provide the above-mentioned objects.

The present invention has the following technical features in order to achieve the above-described problems.

One embodiment of the gas insulated switchgear according to the present invention comprises: a first movable body; A first contact part movably provided on the first movable part body; A first rod for moving the first contact part with respect to the first movable part body; A second movable body facing the first movable body; A second contact part movably provided in the second movable part body and capable of contacting and separating from the first contact part; A link portion for generating movement of the second contact portion with respect to the second movable body; And an induction unit for inducing a linear motion of the second contact part.

The link unit includes a second rod movably installed in the second movable unit body and integrally moving with the first rod; A bracket fixed to the second movable body; A first link which is rotated about a rotation axis fixed to the bracket by the movement of the second rod and a slot which is connected to the second contact portion and which has a slot for converting the rotational motion of the first link into a rectilinear motion 2 link.

The guide portion is a linear guide formed on the bracket, and the second link is guided along the guide portion to induce a linear movement of the second contact portion.

In addition, the second rod is provided with a latching pin, and the first link is provided with a hook which contacts and separates from the latching pin.

The aspect of the configuration can cause a stroke of the second contact sufficient despite the small link length by the first link provided with the hook of the link portion. In addition, when the second contact is moved, it is possible to prevent the rotation direction of the second contact by the rotating link through the linear guide, thereby preventing the durability of the link portion from deteriorating.

The present invention has the following effects with the above-described configuration.

The gas insulated switchgear according to the present invention can effectively form the structure of the link portion for determining the stroke of the second contact so that the stroke of the second contact can be extended to increase the gap distance between the contacts without increasing the size of the device, And it has an effect of enhancing the breaking performance.

Further, the gas insulated switchgear of the present invention can prevent the second contact point from shifting in the moving direction by the rotating link when the second contact is moved, thereby preventing the gas contact insulator through the linear guide, thereby further improving the durability of the gas insulated switchgear .

1 is a schematic view of a conventional gas insulated switchgear.
2 is a schematic diagram of one embodiment of a gas insulated switchgear of the present invention.
FIG. 3 is an operational view showing the operation of the embodiment of FIG. 2;

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

Fig. 2 shows an embodiment of the gas insulated switchgear according to the present invention. One embodiment of the gas insulated switchgear according to the present invention is divided into two parts, a first movable part and a second movable part.

Referring to FIG. 2, the first movable unit includes a hollow body 100, a cylinder 110 movably disposed in the body 100, a first contact unit 120 movably provided in the first movable unit body, A first rod 140 for moving the first contact part with respect to the first movable part body, and a nozzle 120 provided at the end of the cylinder. The cylinder 110, the nozzle 120 and the first contact part 130 are connected to the first rod 140 extending to the rear side of the first movable body 100 to move integrally with the body 100 do.

A compression chamber 150 is formed in the cylinder 110, and an insulated gas is filled in the compression chamber 150. The compression chamber is reduced in volume by the movement of the cylinder interlocked with the first rod, and the insulated gas inside can be compressed. The compressed insulating gas is injected toward the first contact part 130 and the second contact part 210, which will be described later, through the nozzle 120 communicated with the compression chamber.

The second movable part includes a second movable body 200 facing the first movable body 100, a second movable part 200 movably provided in the second movable part body and capable of contacting and separating from the first contact part, A link portion for generating movement of the second contact portion with respect to the second movable body, and an induction portion for inducing a linear movement of the second contact portion.

The second movable part body 100 is formed in a hollow shape at a position facing the first movable part. A second contact part 210 is provided in the body 200. However, the second contact part 210 is not completely fixed to the body but can be moved a predetermined distance.

A link portion for moving the second contact portion through the rotation or the like is connected to the body 200 at an end of the second contact portion 210. The link portion is formed by combining several configurations. Referring to FIG. 2, the link unit includes a second rod 220 movably installed in the second movable unit body and interlocked with the first rod integrally, a bracket 260 fixed to the second movable unit body A first link 250 which is rotated about a rotation axis fixed to the bracket by the movement of the second rod, and a second link 250 connected to the second contact portion to rotate the rotation movement of the first link into a linear motion, And a second link 230 having a first link 230 and a second link 230.

The second rod 220 is movably provided on the body 200 of the second movable part. In addition, the second rod 220 may be connected to the nozzle 120 and may move integrally with the first rod 210 of the first movable part.

The second rod 220 is provided with a locking pin 240. The locking pin 240 contacts and separates from the hook 251 provided on the first link 250 to be described later, (Not shown).

The bracket 260 is fixed to the body 200. The bracket 260 is formed to have a rectangular cross section in the hollow body 200 in the embodiment of FIG. However, this is only an example, and if the second contact part 210 can be fixed to the body 200 and the first link 250 to be described later can be rotated And may correspond to the bracket 260 of the present invention.

The first link 250 is rotated about the rotation axis 252 fixed to the bracket by contacting the engagement pin 260 protruding from the second rod 220. Specifically, a hook 251 is formed at one end of the first link 250, and the hook 251 is formed in a hook shape so as to be hooked on the hooking pin 260.

Meanwhile, a second link 230 having a slot 231 is formed at an end of the second contact part. Here, a connection pin 253 which can be moved along the slot 231 is provided at the other end of the first link 250.

The bracket 260 may be provided with a first stopper 261 and a second stopper 262 for setting a rotation limit of the first link. The first stopper 261 protrudes from one side of the rotation shaft 252 and the second stopper 262 protrudes from the other side of the rotation shaft 252. So that the hook-shaped first link 250 sets the rotation limit to both sides of the rotation. This is a structure for improving durability by preventing breakage of the second contact portion and other devices due to excessive rotation of the first link.

The bracket 260 is formed with an induction part. 2, the guide portion is a straight guide formed on the bracket. That is, referring to FIG. 2, the guide portion is formed of two groove-shaped guides 263a and 263b formed in parallel along the movement path of the second contact portion.

Here, protrusions can be formed on both sides of the second link so as to be received in the two guides 263a and 263b formed in the groove shape. Accordingly, the second link is guided along the groove-shaped guide portion to induce the linear motion of the second contact portion.

FIG. 3 shows a process of inducing the linear motion of the second contact portion. 3 (a) shows the initial state of the shutdown operation. Initially, the second contact portion 210 and the first contact portion 130 are in contact with each other. Also, the first link 250 is not in contact with the retaining pin 260 of the second rod. Here, the first rod moves in the left direction in Fig. 3 (a).

In FIG. 3 (b), the first contact portion 130 and the nozzles are moved by the movement of the first rod 140, and the contact points are separated from each other. Here, the second rod 220 is also moved in conjunction with the movement of the first rod, and the fixed second contact portion 210 is relatively moved as shown in Fig. 3 (a). The hook 251 of the first link 250 is caught by the engagement pin 260 and the first link 250 is rotated about the rotation axis 252 by the movement of the second rod 220 .

Here, the connection pin 253 of the first link is rotated as the first link, the connection pin 253 is relatively slid along the slot 231 of the second link 230, As shown in Fig. That is, the rotational motion of the first link 250 is converted to the linear motion of the second contact part 210 by the slot 231 and the connecting pin 253. Here, the second contact part is linearly moved along the guides 262a and 263b of the guide part connected with the second link. This prevents the shift of the movement path that may occur in the second contact portion according to the rotation of the first link.

FIG. 3 (c) shows the final blocking state. The hook 260 of the second rod which rotates the first link 250 is released from the hook 251 of the first link in accordance with the movement of the second rod and the second contact part 210 moves away from the hook 251 of the first link, (130).

The above-described gas insulated switchgear using the contact movement in both directions increases the separation distance between the contact points by rotation of the link when the contacts are separated from each other. Whereby the first link provided with the hook of the link portion can generate a sufficient stroke of the second contact portion despite the small link length. Accordingly, it is possible to sufficiently secure the inter-electrode distance to prevent the insulation breakdown of the gas insulated switchgear and to improve the breaking performance.

In addition, the side of the above-described configuration can prevent the rotation of the second contact due to the rotating link during the movement of the second contact through the linear guide, thereby preventing the durability of the link portion from deteriorating.

While the preferred embodiments of the present invention have been described with reference to the accompanying drawings, it is to be understood that the scope of the present invention should not be construed as being limited to the embodiments and / or drawings, do. It is to be expressly understood that improvements, changes and modifications apparent to those skilled in the art are also within the scope of the present invention.

100: first movable part body 110: cylinder
120: nozzle 130: first contact part
140: first rod 150: compression chamber
200: second movable part body 210: second contact part
220: second load 230: second link
231: Slot 240: Engagement pin
250: first link 260: bracket
263a, 263b: guides of guide portions

Claims (4)

A first movable body;
A first contact part movably provided on the first movable part body;
A first rod for moving the first contact part with respect to the first movable part body;
A second movable body facing the first movable body;
A second contact part movably provided in the second movable part body and capable of contacting and separating from the first contact part;
A link portion for generating movement of the second contact portion with respect to the second movable body;
And an induction part for inducing a linear movement of the second contact part,
The link portion includes a second rod movably provided in the second movable part body and integrally moved by being interlocked with the first rod; A bracket fixed to the second movable body; A first link which is rotated about a rotation axis fixed to the bracket by the movement of the second rod and a slot which is connected to the second contact portion and which has a slot for converting the rotational motion of the first link into a rectilinear motion 2 link,
Wherein the guide portion is formed of two groove-shaped guides formed in parallel along the movement path of the second contact portion, protrusions each capable of being received in the groove-shaped guide are formed on both sides of the second link, 2 link is guided along the guide portion to induce linear movement of the second contact portion,
Wherein the bracket is provided with a first stopper protrudingly formed on one side of the rotating shaft and a second stopper protruding from the other side of the rotating shaft to set a rotation limit of the first link, Opening and closing device. delete delete The method according to claim 1,
The second rod is provided with a latching pin,
Wherein the first link is provided with a hook which comes into contact with and separates from the engagement pin.

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