KR101654561B1 - Conductor variable type Gas insulated switchgear for maintenance of current transformer - Google Patents

Abstract

The present invention relates to a gas insulated switchgear for use in a substation, comprising: a shielding part including two contacts which are detachably in contact with each other; and one of the two contacts being energized with a power source side, And at least one of a coupling portion on the side of the shielding portion or a coupling portion on the side of the conductor is detachably formed as a member which is disposed between the shielding portion and the one end of the conductor portion to energize the shielding portion and the conductor portion, And a casing part surrounding the shielding part and the outside of the conductor part. The casing part is opened at a predetermined side surface so that the other end of the conductor part is connected to the power source side or the load side. For CT maintenance with a structure that can be easily lifted when needed And to provide a conductive modulation gas insulated switchgear.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a conductor insulated switchgear for maintenance of CT,

[0001] The present invention relates to a gas insulated switchgear, and more particularly to a gas insulated switchgear having a horizontally oriented conductor-variable gap generating link in which a housing and a device inside the enclosure can be easily drawn out for maintenance of a current transformer And more particularly to a gas insulated switchgear.

The Gas Insulated Switchgear (GIS) is a gas insulated switchgear (SFG) that is filled with SF6 gas and contains a circuit breaker (CB), a current transformer (CT), a disconnector (DS), a main bus (MA), an earthing switch (VT), a bushing (BUSHING), a lightning arrester (LA), and a conductor connecting each device. The gas insulated switchgear quickly disconnects the line when abnormal current flows due to ground fault, short circuit or other cause of accident in substation to transmission line.

Especially, since the gas insulated switchgear has the ability to extinguish more than 100 times as compared with the conventional air insulated switchgear, the insulation ability is excellent, and the device can be downsized, the air insulated switchgear is gradually replaced by the gas insulated switchgear.

Generally, GIS is known to be highly reliable and does not cause accidents and does not require maintenance, but the reality is somewhat different. According to the accident statistics of the Working Group under the International Large Power Network Technology Conference, which took 25 years from 1967 to 1992, an average of 0.9 incidents of insulation accidents per 100 gas insulated switchgear installations were reported.

The major cause of accidents was caused by the load applied to the transformer, epoxy insulation of the transformer for a long time, and the particles on the surface of the insulator or on the conductor, but the number of the breaker, disconnector,

First of all, prevention of accidents is important. Preventive diagnosis techniques are introduced for areas where anomalous signs or deteriorations occur. However, once equipment malfunctions occur, rapid maintenance work must be performed for normal operation. In order to do so, the apparatus should be able to be easily separated and dismantled. However, as shown below, the disassembly of the conventional gas insulated switchgear is considerably difficult and complicated.

Fig. 1 is an external view of a housing of a conventional gas insulated switchgear, and Fig. 2 shows a conductor which conducts a breaker and a neighboring appliance inside a housing of a conventional gas insulated switchgear. Referring to FIG. 1, in general, the parts where the frequencies of the equipment are higher than those of the apparatuses and the continuous maintenance is requested are the breaker unit A and the breaker unit B, and the breaker unit A and the current transformer unit B, And the bushing are connected to each other in order to repair and separate separation and salvage are necessary.

Fig. 2 corresponds to the breaking unit unit A and the current transformer unit B in Fig.

The breaker 1 and the spacer 8 are connected to each other in Fig. 2 in order to lift the enclosure surrounding the breaker unit A, the current transformer unit B and the breaker unit A and the current transformer unit B, The conductor 2 connecting between the two conductors should be disconnected. The conductor 2 is connected to the breaker at one end by bolts 3a and 4a and the other end is connected to the spacer 8 by elastic gripping means 3b and 4b. Therefore, in order for the breaker unit A and the current transformer unit B to be separated for repairing, all of the joints 3a, 3b, 4a, and 4b of the respective zones must be dismantled, And the current transformer unit B must be shifted to the left by the K section shown in Fig. If there is no movement by the interval K, the right end, which is the other end of the conductor, is caught by the flange on the side of the spacer 8, that is, the inner circumferential surface of the adjacent enclosure.

However, in order for the breaker unit A and the current transformer unit B to move by the interval K, the control panel unit P shown in FIG. 1 must also be moved to the left by K intervals.

As a result, all of the peripherals must be moved together for the lifting operation of the breaker unit A and the current transformer unit B, so that the labor and time required for the repair are considerable.

In the prior art, a technology having a similar problem consciousness is hard to be found. As a peripheral technology, there has been proposed a technique of replacing a branch circuit unit for maintenance of a gas insulated switchgear apparatus, which is disclosed in Japanese Laid-Open Patent Publication No. 1999-0045635 Open date: June 25, 1999) and a method of exchanging the gas circuit breaker unit and the branch circuit unit thereof.

In the prior art, the first and second main bus lines (1, 2) and the circuit branching from both bus lines are connected to a gas insulated switchgear (2) connected by a unit housed in a housing (21, 22) filled with high- The main bus disconnecting unit 33 is rotated and reconnected in the state where either the first main bus line 1 or the second main bus line 1 is in an electrically charged state and then the main bus line disconnecting unit 33 And then the other main bus line is electrically charged to extract the gas from the main bus disconnecting unit 33. After that, the branch circuit unit 23 to be subjected to the maintenance is disconnected from the main bus line A gas insulated switchgear and a method for exchanging a branch circuit unit.

According to the above-described prior art, there is no need to prepare the short-circuit bus unit in advance and one of the two lines can be used as a short-circuit bus unit at the time of an accident, so that the repair can be easily performed without turning off the substation.

However, there are many types of equipment abnormality in the gas insulated switchgear, and the gas insulated switchgear is inevitably lifted for complete maintenance, but at present, the gas insulated switchgear equipped with means for easily performing the lifting operation It is a fact.

That is, in the gas insulated switchgear, in order to quickly lift the current transformer CT, the conductor must be easily changeable in the horizontal direction, but no means for enabling it has been found in the prior art.

Published Japanese Patent Application No. 1999-0045635 (published on June 25, 1999)

SUMMARY OF THE INVENTION Accordingly, the present invention has been made keeping in mind the above problems occurring in the prior art, and it is an object of the present invention to provide a structure capable of varying a conductor in a horizontal direction so that a complicated disassembly process and a breaker and a current transformer can be lifted without interfering with a peripheral device. The present invention provides a conductor variable type gas insulated switchgear for CT maintenance of branches.

In order to accomplish the above object, a conductor variable type gas insulated switchgear for CT maintenance according to the present invention comprises a shielding part including two contactors detachably contacted with each other, A shielding part provided on each of the shielding part and the conductor part and having a current transformer disposed on an outer circumferential surface thereof to flow the current to the current transformer and a member disposed between one end of the shielding part and the conductor part to energize the shielding part and the conductor part, One coupling portion is formed to be detachable so as to form a gap generating link portion for horizontally varying the conductor and a blocking means for blocking the blocking portion and the outside of the conductor portion. And a casing portion in which a protruding portion to be opened is formed.

Preferably, the conductor variable type gas insulated switchgear for maintenance of the CT is disposed between the other end of the conductor unit and the adjacent equipment to connect the conductor unit and the adjacent equipment. The elastic unit includes elastic means for pressing the other end of the conductor unit. And may further include a coupling link portion.

The first embodiment of the gap creating link portion providing a space in which the conductor can be horizontally varied is formed long in the longitudinal direction and vertically arranged with respect to the conductor portion, And the hinge shaft of one end is coupled to one end of the conductor portion and the other end of the hinge shaft is coupled to the blocking portion.

The second embodiment of the gap creating link portion has a predetermined length and is arranged to be inserted between the shielding portion and the conductor portion, and a fastening arm protruding toward either the blocking portion or the conductor portion protrudes from either end of the gap generating link portion, And the conductor portion is coupled to the fastening arm by the fastening member.

According to another aspect of the present invention, there is provided a conductor-variable gas insulated switchgear for maintenance of CT according to the present invention, wherein a clearance is formed between a conductor portion and a shielding portion by a gap generating link portion, Since the current transformer can be lifted, the labor, time, and cost required for the maintenance and dismantling work can be remarkably reduced.

1 is a front view showing the appearance of a conventional gas insulated switchgear,
2 is a front sectional view showing a connecting structure of a conductor portion and a breaking portion in a conventional gas insulated switchgear,
3 is a conceptual diagram showing a conventional technique,
4 is a front sectional view showing a cut-off portion of a conductor-variable type gas insulated switchgear for CT maintenance according to the present invention,
5 is a partial perspective view showing a cut-off portion of a conductor-variable type gas insulated switchgear for CT maintenance according to the present invention,
FIG. 6 is a front sectional view showing a part to be lifted in a conductor variable type gas insulated switchgear for CT maintenance according to the present invention,
7A, 7B, 7C and 7D are a partial perspective view and a side view showing, in order, the action of the first embodiment of the gap creating link portion of the present invention,
8A is a partial perspective view showing a second embodiment of the gap creating link portion of the present invention,
8B is a partial perspective view showing a third embodiment of the gap creating link portion of the present invention,

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

4 is a front cross-sectional view showing a shielding part 10, a current transformer 25, a conductor part 20 and a housing part 40 in a conductor variable type gas insulated switchgear 5 for maintenance of CT according to the present invention. And FIG. 6 is a view showing a lifting region 100 to be separated for maintenance

4 and 6, a conductor variable type gas insulated switchgear 5 for CT maintenance according to the present invention includes a first contact 11 and a second contact 2, A shielding part 10 including a contactor 12 and a conductor part 20 which is energized with one of the two contacts 11 and 12 on the power source side and the other with a load side, A link arm 301 and a link arm 301 which are elongated in the longitudinal direction and which are disposed between one end of the link member 301 and the one end of the link member 301, One of the two shafts is coupled to a shielding portion side protrusion 305 formed on the outer circumferential surface of the shielding portion 10 and the other is coupled to the conductor portion 20 side And the link arm (301) is electrically connected to the cut-off portion (10) and the conductor portion (20) The shaft 21 is detachably connected to the shaft 305 so that the shaft 21 is separated from the shaft portion side protrusion 305 so that the conductor 21 is horizontally varied in the direction of the shaft portion 10 by the thickness of the shaft portion side protrusion 305 A sealing portion 30 for sealing the gap forming link 30 and the outside of the shielding portion 10 and the conductor portion 20 is provided with a hollow portion for forming an opening portion so that the other end of the conductor portion 20 is connected to the adjacent device 40 and a member disposed between the other end of the conductor section 20 and the adjacent apparatus for detachably connecting the conductor section 20 and the adjacent apparatus and elastically pressing and restraining the other end of the conductor section 20 And an elastic coupling link portion 50.

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Since the overall structure of the conductor variable type gas insulated switchgear (5) for maintenance of CT according to the present invention has been briefly described, the details of the detailed structure and the relationship between the respective structures will be described in detail below.

Referring to FIG. 4, the breaker 10 of the present invention is provided with a first contact 11 and a second contact 12 inside thereof, and an abnormal current flows due to an accident caused by a ground fault, a short circuit, The two contacts 11 and 12 are separated from each other and contact is maintained in a normal situation. The structure of the blocking portion 10 is the same as the blocking portion of the conventional gas insulated switchgear, and the operating method and the detailed structure of the contactor can be adopted as any known technique.

In FIG. 4, the conductor 21 of the present invention is in the form of a straight line, and is formed integrally with no cut-off portion in the middle. The concrete shape of the conductor 21 may be any conventional known technique, but preferably, an integrally-formed and straight-shaped conductor having no cut-off section in the middle is disposed as shown in FIG.

The current transformer 25 is disposed in the form of wrapping around the outer circumferential surface of each conductor and positioned in the protrusion in the housing portion 40. However, the position of the current transformer 25 may be disposed in the adjacent enclosure, and the position of the current transformer 25 in Fig. 4 is one embodiment.

In FIG. 4, since the current transformer 25 is arranged to surround the conductor, the conductor flows through the current transformer. Referring to FIGS. 4 and 5, a protruding portion is formed on the side surface of the hinge portion 40 to connect the hinge portion 40 as a cylindrical shape and the adjacent enclosure in which the adjacent device is embedded. The protrusion portion includes a hinge portion 40, And a current transformer 25 through which the conductor 21 flows.

The end of the protrusion is open and connected to the adjacent enclosure in which the adjacent device is embedded. The protrusions and the adjacent enclosures are each defined by a spacer 8, and the ends of the protrusions are opened so that the conductors 21 can be connected to the adjacent enclosures. Therefore, the opening portion formed on the side surface of the housing portion 40 becomes the end of the cylindrical protruding portion.

The gap generating link portion 30 in FIG. 4 serves to energize one end of the conductor 21 to the first or second contacts 11 and 12, and more importantly, The conductor 21 protrudes more than the end of the protrusion of the housing part 40 so that the conductor 21 is horizontally variable to the left in FIG. 4 so as to prevent interference with the end of the adjacent housing, To provide space that can be

4, the spacer 8, which compartmentalizes the hermetically-sealed portion 40 and the adjacent hermetically sealed container 40, is not disposed at the interface between the adjacent hermetically-sealed portion 40 and the adjacent hermetically sealed portion 40, but is disposed at a predetermined position inside the adjacent hermetically- Since the conductor 21 connected to the conductor 8 is caught by the end of the adjacent housing if it is lifted up directly, it is necessary to provide a space in which the conductor 21 can be horizontally changed to the left in FIG.

In this case, the distance to be shifted to the left corresponds to a section indicated by k, referring to FIG.

The gap generating link portion 30 of FIG. 4 is one embodiment, and FIGS. 8A and 8B show still another embodiment of the gap creating link portion 30. As shown in FIG. 7A to 7C are diagrams showing, in a time order, the principle by which a gap is generated due to the gap creating link portion 30. FIG.

7A to 7D, a blocking shaft side fixing shaft 303 is connected to the blocking portion side of both ends of the link arm 301 and the link arm 301, and a hinge Side hinge shafts 304 serving as shafts are coupled to each other while the shafts side fixing shafts 303 and the conductor hinge shafts 304 are parallel to and opposite to each other. At this time, the blocking shaft side fixing shaft 303 among the blocking side fixing shaft 303 and the conductor side hinge shaft 304 is detachably coupled to the link arm 301.

When the gap generating link portion 30 is separated from the shielding portion 10 by removing the shielding shaft side fixing shaft 303, the link arm 301 is rotated as shown in FIG. 7B, (G) of FIG. 7C is generated between the conductor (10) and the conductor (G) as much as the gap thus created is moved to the left in the drawing. 7C, which is a perspective view, it can be easily judged at which portion the gap G is generated, referring to the side view of FIG. 7D.

7A to 7D, the fixing shaft is coupled to the blocking portion 10 because when the hinge shaft is coupled to the blocking portion 10, the stable coupling between the conductive portion 20 and the blocking portion 10 It is hard to maintain.

Referring to FIG. 6, the role of the gap creating link portion 30 will be described. The area 100 where the lifting area required for lifting is surrounded by a thick dotted line in Fig. 6 for repairing in the gas insulated switchgear 5 is shown. The protruding portion is formed and the conductor 21 protrudes to the outside more than the protruding portion so that the shielding portion 40 surrounding the shielding portion 10 and the outside of the conductor portion 20 and the current transformer 25 is protruded, Is coupled to the spacer (8) adjacent to the insulating switching device (5). The spacer 8 functions to prevent the leakage of the insulating gas by dividing each unit connected to the isolator and the bushing in the gas insulated switchgear 5 according to the present invention for each section.

At this time, the end of the projected portion located at the rightmost position in the drawing portion of the hull 40 is formed by a flange extending perpendicularly to the projecting direction, and the joint portion with the adjacent hull in which the adjacent device is built is also formed as a flange, A gas-tight structure is created.

Referring to FIG. 4, the right end of the conductor 21 is shown assembled with the elastic coupling link 50 connected to the spacer 8 of the adjacent housing. The elastic coupling link portion 50 is a member for detachably connecting the conductor 21 to the adjacent spacer and resiliently presses and restrains the right end outer peripheral surface of the other end of the conductor portion 20 so that the coupling state is maintained.

As shown in FIG. 2, since there is no space to push the conductor 21 to the left when separating the conductor 21 from the elastic coupling link 50 in the conventional gas insulated switchgear, The disengagement of the elastic coupling link portion 50 becomes impossible.

In this case, in order to move the conductor to the left in the conventional gas insulated switchgear, the control panel unit 6 itself of FIG. 4 itself is first removed to the left, and then the conductor is moved not only to the conductor but also to the housing portion 40 All equipment must be moved to the right simultaneously.

Even if the conductor 21 is moved to the left, if the right end of the conductor 21 protrudes inside the adjacent housing portion in which the adjacent device is housed, interference with the upper inside end of the adjacent adjacent housing portion occurs and the housing 21 can not be lifted up . That is, in FIG. 4, the right end of the conductor 21 in the drawing is caught by the adjacent enclosure.

That is, since the conductor portion 20 protrudes more than the end of the lateral projection of the housing portion 40, the conductor portion 20 is moved to the left in the drawing, so that the lifting portion can be lifted. Therefore, a space is required to allow the conductor 21 to be moved to the left by the gap generating link portion 30. [

In the past, as described above, since there is no gap generating link portion 30, if there is interference with the adjacent enclosure, the lifting work for repairing is much more complicated and laborious and time consuming.

In the conventional gas insulated switchgear, the bolts 3a, 3b, 4a, and 4b of each zone in FIG. 2 must be dismantled in the process of dismantling for lifting, while in order to secure space for lifting, The part 6 was also disassembled and moved to the left. If necessary, the controller base 7 connected to the control panel part 6 was also moved to the left.

In this case, lifting of the lifting area for repair requires a large amount of time, which is unsuitable for substation facilities requiring continuous operation.

Therefore, in the present invention, the gap generating link portion 30 is provided so that only the conductor portion 20 can be changed in the horizontal direction.

In the case of the gap generating link portion 30 of the embodiment of Figs. 4 to 7C, the process of generating the gap is shown in time sequence in Figs. 7A to 7C. The link arm 301 can freely rotate around the conductor side hinge shaft 304 by removing the blocking shaft side fixing shaft 303 connected to the blocking portion 10 in FIG.

7B, if the link arm is rotated by a predetermined angle so as not to overlap with the protrusion 305 protruding for hinge connection between the link arm 301 and the blocking portion 10, the entire portion of the conductor portion 20 A gap G that can be horizontally varied to the left on the drawing is generated by a predetermined interval.

7d are shown in side views so as to more clearly understand the point where the gap G is formed.

In this case, the link arm 301 is connected to the blocking portion 10 side by the fixing shaft 303 on the side of the blocking portion 10 and is hinged to the side of the conductor portion 20 so that the link arm 301 is connected to the conductor portion 30, it is not necessary to disassemble both the shielding-side fixed shaft 303 and the conductor-side hinge shaft 304. That is, if only the shielding-portion-side fixed shaft 303 is disassembled, the conductor-side hinge shaft 304 is rotated, and a clearance can be secured.

In order to further simplify the disassembling process, it is preferable that the method of coupling the right end of the conductor portion 20 and the spacer 8 to each other is performed by using the elastic coupling shown in FIG. 4, So that the link portion 50 is provided.

Although the elastic coupling link 50 is not clearly shown in FIG. 4, since the elastic coupling structure itself is a known means for coupling the right end of the conductor in an elastic manner, a detailed description thereof will be omitted, There is no limit to the specific form as long as it can be done.

The disassembly of the conductor portion 20 and the elastic coupling link 50 in the disassembling process is performed naturally in the process of moving the conductor 20 to the left so that the conductor 20 and the elastic coupling link 50 are separated The dismantling operation can be performed more easily since the dismantling operation for the dismantling is not necessary.

8A and 8B show another embodiment of the gap generating link portion 30. As shown in Fig. 8A and 8B is that the link member 311 and 321, which are electrically separated from each other by a certain gap between the shielding portion 10 side and the conductor portion 20 side, are inserted and fixed.

8A and 8B is that the gap generating link portion 30 is disposed between the blocking portion 10 and the conductor portion 20 and the link members 311 and 321 for energizing the blocking portion 10 and the conductor portion 20 And fixing means 312, 313, 322, 323, 324 for detachably connecting the link members 311, 321 to at least one of the blocking portion 10 and the conductor portion 20.

8A, the fixing means is a fixing arm 312 and the link member 311 is fixed to the side of the blocking portion 10 or the side of the conductor portion 20 by the fixing arm 312 and the coupling member 313 And the remaining unbonded portion is only contacted for energization without a separate coupling structure. In this case, in FIG. 8A, the fixing arm 312 is connected only to the blocking portion 10 side, but it is not necessarily the side of the blocking portion 10, but the fixing arm 312 may be coupled to the conductive portion 20 side, And the side of the conductor portion 20 may be connected by the fixing arm 312.

The fixing means in the embodiment of FIG. 8B is characterized in that the coupling is performed by the link clamp 322 instead of the fixing arm 312 of FIG. 8A. At this time, the link clamp 322 is not necessarily coupled to the blocking portion 10 as shown in the drawing, but may be coupled to only the side of the conductor portion 20 or may be elongated, so that both sides thereof may be coupled.

In the present invention, a gap is formed between the conductor portion 20 and the shielding portion 10 by means of three embodiments to provide a means of making the conductor only horizontally changeable. However, in the case of the simple modification of this embodiment, It will be apparent that other variant embodiments are within the equivalents of the embodiments of the present invention.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the inventions. It will be apparent to those of ordinary skill in the art.

5: Conductor variable type gas insulated switchgear for CT maintenance 6: Control panel part
7: Controller base 8: Spacer
10: cut-off portion 11: first contact
12: second contactor 20: conductor part
21: Conductor 25: Current transformer
30: gap generating link portion 40:
41: upper cover
42: flange bolt 43: lower bolt
50: Elastic coupling link portion 100: Lifting portion
301: Link arm 303: Fixing shaft on the blocking part
304: conductor side hinge shaft 305: shielding portion side protrusion
311: Link member 312: Fixing arm
313: Fixing arm fastening member 321: Link member
322: Link clamp 323: Coupling ring
324: Clamp coupling member

Claims (7)

A blocking portion including two contacts detachably in contact with each other;
One of the two contacts being electrically connected to the power supply side and the other being connected to the load side;
A link arm formed to be elongated in the longitudinal direction and two shafts connected to both ends of the link arm and arranged horizontally to each other, and one of the two shafts is coupled to a protrusion on the blocking portion formed on the outer peripheral surface of the blocking portion And the other is connected to the conductor portion side to energize the blocking portion and the conductor portion,
The link arm is detachably assembled to a shaft coupled to the protrusion of the blocking portion, thereby separating the shaft from the protrusion of the blocking portion to thereby horizontally vary the conductor in the direction of the blocking portion by the thickness of the blocking portion side protrusion;
A sealing part enclosing the shielding part and the outside of the conductor part, the sealing part comprising: a hollow part formed with an opening part for connecting the other end of the conductor part to the adjacent device; And
And a resilient coupling link portion disposed between the other end of the conductor portion and the adjacent device for detachably coupling the conductor portion and the adjacent device and resiliently pressing and resting the other end of the conductor portion, Variable gas insulated switchgear. delete delete The method according to claim 1,
Wherein a shaft coupled to the blocking portion side of the two shafts is a detachable fastening member as a fixed shaft and a shaft coupled to the conductor portion is a hinge shaft. The method according to claim 1,
The gap generating link portion is composed of a link means which is disposed between the blocking portion and the conductor portion and energizes the blocking portion and the conductor portion and a fixing means which detachably couples the link means to at least one of the blocking portion and the conductor portion. A conductor variable type gas insulated switchgear for CT maintenance. 6. The method of claim 5,
Wherein the fixing means is a fixed arm having one end fixedly coupled to the link means and the other end fixed to the blocking portion or the conductor portion with a fastening member. 6. The method of claim 5,
Wherein the fixing means is a clamp for simultaneously enclosing one end of the blocking portion or the conductor portion and the link means.

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