KR20160122642A - Gas-insulated surge arrester - Google Patents

Abstract

The present invention relates to a surge arrester (1) comprising at least one active part (2) arranged in a fluid-tight housing (3). A particular advantage is formed in the embodiment with three active portions (2). The housing 3 includes a side wall 4 and a bottom 5 and is closed by a cover 6 on the side opposite to the bottom 5. The side wall 4 and the bottom 5 are formed as a single piece, in particular cast into a single piece, for example of aluminum or steel. The bottom 5 comprises a self-opening 7 for each active part 2 through which the active part 2 can be inserted into the housing 3. To this end, the shape and width of the opening 7 should be dimensioned such that the assembled active part 2 can be inserted into the housing 3 through the opening. Each of the openings 7 is closed in a fluid-tight manner by a closure 8. Preferably, the surge arrester 1 comprises a plurality of, in particular three, active portions 2. For each of the active parts 2, an opening 7 is provided in the bottom 5, i.e. in the three active parts 2, the bottom 5 comprises three openings 7. This type of housing 3 is made inexpensive, for example because the bottom 5 is cast with the side wall 4 in one piece, so that the bottom, which is usually only produced by cutting, is removed. This type of surge arrester 1 is also easily assembled because the active portions 2 are not inserted into the cavity 7 through the openings 7 but can be inserted and assembled individually through the openings 7 Because.

Description

[0001] GAS-INSULATED SURGE ARRESTER [0002]

Surge arrester is a protection system for high voltage or medium voltage switches, for example, which protects other components of the switch by inducing such overvoltage to ground when an overvoltage occurs due to a lightning stroke or malfunction of another subsystem.

Surge arresters of this type include at least one active part with a cylindrical inductive element, which in turn comprises a varistor column consisting of a cylindrical individual varistor element and extending along the cylindrical axis. The varistor element is characterized by voltage-dependent resistance. At low voltage, the varistor element acts as an insulator. From a certain threshold voltage depending on the material, the varistor element exhibits good conductivity. The varistor element is usually made of a metal oxide such as zinc oxide. The inductive element is limited at both ends by the end fixture which forms electrical contact to the switchgear and ground. In addition, the varistor column must be bound under pressure to ensure good electrical contact even at mechanical load. This can be done preferably by tensioning a tension element made of glass fiber reinforced plastic, for example a cable or a rod, under tension in the end fixture. At this time, the tensile element surrounds the varistor column and forms a cage around it.

For use in gas insulated switchgear, the surge arrester includes a fluid-tight housing surrounding the inductive element. In this case, the housing is filled with a fluid, usually sulfur hexafluoride (SF ₆ ), to increase the dielectric strength. The housing is usually made of metal and electrically grounded. One end fixture of the induction column is grounded by a contact which is guided through the housing. The other end fixture is electrically connected to the high voltage contact located outside the housing through the housing feedthrough and used for connection to the switchgear.

An object of the present invention is a surge arrester for a gas insulated switchgear.

EP 2 846 333 A1 discloses a surge arrester comprising three active parts and having a gas insulated housing. The housing comprises a cast cylindrical housing, a high voltage side cover having a high voltage side feedthrough for each active portion, and a ground side cover. Such covers include a large number of openings and fastening elements, which are complicated to manufacture and costly. Also, the assembly of the surge arrester is complicated because all active parts must be fixed to the cover. The cover is then seated on the housing shell with the active portion secured to the cover. In this case, the active portion must be assembled to the high voltage side cover within the corresponding fixing portion, which is cumbersome.

An object of the present invention is to provide a surge arrester that can be manufactured at low cost and can be simply assembled.

According to the present invention, a surge arrester is provided that includes at least one active portion arranged in a fluid-tight housing such as that used in a gas insulated switchgear. As is known in surge arresters, the active part is a column of resistances according to voltage clamped to two end holders, a so-called varistor. The present invention relates to surge arresters having one or more active portions. However, a particular advantage is formed in embodiments with three active moieties. The housing includes a side wall and a bottom, and is closed by a cover on the side opposite to the bottom. The sidewalls and bottom are single-ply with a single piece, for example aluminum or steel. The bottom includes its own opening for each active portion, through which the active portion can be inserted into the housing. To this end, the shape and width of the opening are dimensioned such that the assembled active part can be inserted into the housing through the opening. Each opening is closed fluid tightly through the closure. Preferably, the surge arrester comprises a plurality of particularly active portions. For each active portion, an opening is provided in the bottom, where the bottom comprises three openings in the three active portions.

This type of housing is made inexpensive, for example, since the bottom is cast with the side wall and a single piece, so that the bottom, which is usually only produced by cutting, is removed. Also, this type of surge arrester is easy to assemble because the active portions can be inserted and assembled separately through the openings, rather than being inserted and assembled through the openings.

In a preferred embodiment of the invention, each opening is guided through a molded, in particular flanged, flange arranged on the outside. The flange defines an opening perpendicular to the longitudinal axis in the plane. The flange is used to secure the closure, thus facilitating assembly. In particular, the flange can be easily accessed by being convex outward.

Preferably, the outer diameter of the housing gradually narrows toward the bottom and extends toward the cover. Thereby, the inner diameter can be adapted to an insulation gap which increases toward the cover over the height of the housing, whereby the volume can be reduced. This, on the other hand, saves material for the housing and on the other hand saves insulating fluid for filling.

Likewise preferably, the cross section of the closure and the opening is rectangular, in particular square. Alternatively, it is round. These two embodiments enable a particularly simple and inexpensive manufacture of the closure.

In another preferred configuration, the active portion is secured to the closure, which allows for simple assembly.

Preferably, the active portion is electrically connected to the feedthrough conductor of the feedthrough, and the feedthrough conductor is lead through the enclosure electrically insulated against the enclosure. The feedthrough directs the electrical connection from the outside into the housing. The electrical connection is insulated with respect to the housing and, in particular, to the closing portion in electrical contact with the housing. As the electrical connection is guided through the closure, further processing of the housing can be omitted, for example by providing a bore for the feedthrough conductor.

Particularly preferably, the active part is fixed to a feedthrough conductor, which may for example be formed as a bolt. Therefore, the assembling of the active portion becomes easy.

It is particularly preferred that the closure, the feedthrough and the active portion form a preassembled unit outside the housing. A feedthrough is mounted to the closure and the active portion is secured to the feedthrough conductor. This can be performed outside the housing, so that it can be performed more easily than inside the housing with a narrow space condition. The entire preassembled unit can be assembled by inserting the active portion into the opening and the closing portion until it seats on the flange. Then, the closure part is only fixed to the flange.

BRIEF DESCRIPTION OF THE DRAWINGS Fig.

It is possible to provide a surge arrester which can be manufactured inexpensively and simply assembled by the present invention.

1 shows a partial cross-sectional view of a conventional surge arrester.
2 shows a partial cross-sectional view of a surge arrester according to the present invention.
Fig. 3 shows a detailed view of the cross-sectional view of Fig.

Corresponding parts have the same reference numerals in all figures.

Fig. 1 shows the surge arrester 1 known from EP 2 846 333 A1. The encapsulated fluid-tight housing 21 includes a housing wall 22 in the form of a conduit with a flange 38 at the end of the conduit. The flange 38 is secured to the high voltage connecting side 31 with a high voltage feed through 34 and the ground connecting side 32 with a cover 39 closed in a fluid tight manner. The housing 21 is actually formed of a conductive material, such as steel or aluminum, and is grounded during operation. The cover 39 is a plate made of, for example, a metal, and may include a pressure-releasing opening 35 closed by a rupture plate or a thin film not shown. The cover 39 for the active portion 2 arranged in the housing 21 also includes an opening for the ground side feedthrough 15. The high voltage feed-through 34 is comprised of a frame 37 having an insulating portion 36 formed of an electrically insulative material such as a mold resin and has a high voltage feedthrough 34 for each active portion 2 arranged in the housing 21, A contact 28 is inserted into the insulating material. The electrical high voltage potential through the high voltage contact 28 can be guided from the exterior into the housing 21 without the risk of surge between the high voltage and the grounded housing 21.

In the housing 21, at least one active portion 2 is arranged between the ground connecting side 32 and the high-voltage connecting side 31. [ Here, three active portions 2 are arranged in the housing 21, and due to the sectional view, only two of them can be seen. Each active portion 2 includes a cylindrical inductive element 20 extending along the longitudinal axis 30 to the bell. The inductive element 20 is typically formed as a stack of cylindrical varistor elements with a resistance according to the voltage. End fixing bodies 23 and 24 are arranged at the ends of the inductive element 20, respectively. A tensile element 25 made of, for example, a glass fiber reinforced plastic surrounds the inductive element 20 in parallel to the longitudinal axis 30 and is clamped under tension in the end fixtures 23 and 24. The tensile element 25 presses the varistor elements against each other, creates good electrical contact therebetween, and is used to bond the stack. Tension elements are also used, for example, to protect the stack from slips of varistor elements during shipping. The end fixture 23 is inserted or preferably screwed directly onto the feedthrough conductor 16 at the ground connection side 32. The feedthrough conductor 16 represents a ground contact. Thereby, an electrical contact to the outside of the housing 21 is formed, which is connected to the ground during operation.

In the high-voltage connecting side 31, the end fixing body 24 includes the shielding hood 27. The shielding hood is used to shield the edge or edge of the end fixture 24 from an electric field of high voltage.

2 and 3 show an embodiment of the surge arrester 1 according to the present invention. Three active portions 2 are arranged in the fluid-tight housing 3, and due to the cross-sectional view only two or only one of them can be seen. The housing 3 is formed of a conductive material in the form of a pot. The substantially cylindrical side wall 4 is switched to the floor 5 seamlessly in the region of the ground connection side 32. [ This switching is performed by the rounding unit 10. The sidewalls 4 and the bottom 5 are cast into a single piece, for example steel or aluminum.

The housing 3 is closed by the cover 6 on the side facing the bottom 5. The cover 6 is formed as a high-voltage feed-through 34. In the ring-shaped frame 37, a disk-type insulating portion 36 made of, for example, a mold resin is arranged. The high-voltage contact 28 inserted into the insulating portion 36 forms a conductive connection from the inside to the outside of the housing 3. The cover 6 is fixed to the flange 38 of the housing 3 by screws. The high voltage side end fixture 24 of the active portion 2 is coupled into the corresponding indentation of the high voltage contact 28 by a lug and is fixed in a direction perpendicular to the longitudinal axis 30.

The bottom 5 comprises an opening 7 for each active part 2 whose width is such that the active part 2 is moved through the opening 7 into the housing 3 along the longitudinal axis 30 And is dimensioned to be inserted. The cross section of the opening 7 is a square with an actually rounded edge. However, this may be circular.

Along the boundary of each opening 7, the bottom 5 comprises an outwardly convex flange 9. The outside of each flange 9 forms a flat surface on which the closure 8 rests. The flange 9 and the bottom 5 are formed as a single piece with the side wall 4, for example as a single casting part.

The active portion 2 is fixed on the inside of the flange 9. The active part 2 can be fixed directly to the closing part 8 and thus electrically connected thereto or fixed by the electrically insulating intermediate piece.

In the illustrated embodiment, fixation is performed by the feedthrough 15. The feedthrough 15 comprises a feedthrough conductor 16 guided from the outside into the interior of the housing 3 and a two-piece feedthrough body 17 made of an electrically insulating material such as a mold resin. A portion of the feedthrough body 17 lies outside the closure 8 and the other portion lies inside. One or two portions of the feedthrough body 17 may include a seal for the closure 8. The feedthrough conductor 16 penetrates not only the two portions of the feedthrough body 17 but also the closure 8. The closure 8 is preferably made of a conductive material, for example of metal. In this case, the feedthrough conductor 16 is electrically insulated with respect to the closure 8. The feedthrough conductor 16 includes a shoulder that is supported on the feedthrough body 17 at its outer end. The feedthrough conductor comprises a thread at its inner end to which the end fixture 23 of the active part 2 is screwed and secured thereto. Therefore, the active portion 2 is electrically insulated with respect to the closing portion 8 and the housing 3. In this way, the closure 8, the feedthrough 15 and the active part 2 form one unit that can be assembled outside the housing 3. To this end, the feedthrough conductor 16 is inserted through one portion of the feedthrough body 17 and through the bore in the closure 8. A second portion of the feedthrough body 17 from the other side of the closure portion 8 is inserted on the feedthrough conductor 16 and the active portion 2 is threaded onto the feedthrough conductor 16. To this end, the ground-side end fixture 23 of the active part 2 comprises correspondingly oriented threads in the longitudinal direction 30. The fluid seal is ensured by the two seals 19.

The active part 2 is inserted along its longitudinal axis 30 through the opening 7 into the housing 3 until the closing part 8 is seated on the flange 9, (3). The lugs of the end fixture 24 are coupled into the corresponding indentations of the high voltage contacts 28 of the high voltage feedthrough 34 on the opposite side, The closure 8 is secured to the flange 9 by means of a screw 18. The seal 19 ensures that the housing is closed in a fluid-tight manner.

The inner diameter of the housing 3, that is, the width measured perpendicularly to the longitudinal axis 30, narrows toward the bottom 5 and extends toward the cover 6. [ Thus, in the overall wall thickness of the housing 3, the outer diameter of the cover 6, that is, the area on the high voltage side is larger than the area of the bottom 5, i.e., the ground side. In the active part 2, a much higher voltage occurs on the high voltage side than on the ground side. Therefore, the insulation gap should be larger at the higher voltage side than at the ground side, not only between the active portions 2 but also between the active portion 2 and the normally grounded housing 3. [ In the prior art, the housing inner diameter was constant over the length of the housing and dimensioned at the high voltage side as insulation spacing was inevitable. In contrast, the embodiment according to FIG. 2 shows a much narrower housing 3, which is only in the high voltage side region, with a diameter comparable to the prior art over most of the height of the housing 3, And a clearly reduced diameter compared to the prior art. Thereby, on the one hand, the material for the manufacture of the housing is saved, and on the other hand the insulating fluid, for example SF _{6, is} also saved by the reduced volume.

1: Surge arrester
2: active moiety
3: Housing
4: side wall
5: Floor
6: cover
7: aperture
8: Closure part
9: Flange
10:
15: Ground side feedthrough
16: Feedthrough conductor
17: Feedthrough body
18: Screw
19: Seal
20: inductive element
21: Housing
22: housing wall
23: end fixture
24: end fixture
25: Tensile element
27: Shielded hood
28: High voltage contact
30:
31: High voltage connection side
32: Ground connection side
34: High Voltage Feedthrough
35: Pressure release opening
36: Insulation part
37: Frame
38: Flange
39: Ground side cover

Claims (8)

A surge arrester (1) having at least one active part (2) arranged in a fluid-tight housing (3), the housing (3) comprising a side wall (4) and a bottom The side wall 4 and the bottom 5 are formed in a single piece and the bottom 5 comprises an opening 7 for each active part 2, Wherein the active part (2) can be inserted through the opening and each opening (7) is closed in a fluid-tight manner by a closing part (8). 2. Surge arrester (1) according to claim 1, characterized in that each opening (7) is guided through its own flange (9) arranged on the outside at the bottom (5). The surge arrester (1) according to claim 1 or 2, characterized in that the housing inner diameter gradually narrows toward the bottom (5) and extends toward the cover (6). A surge arrester (1) according to claim 1 or 2, characterized in that the enclosure (8) and the opening (7) are rectangular. A surge arrester (1) according to claim 1 or 2, characterized in that each active part (2) is fixed to the closure part (8). 3. A device according to claim 1 or 2, wherein the feedthrough (15) comprises a feedthrough conductor (16) electrically connected to the active part (2), the feedthrough conductor being electrically insulated against the closure part Is guided through the closing portion (8). 7. Surge arrester (1) according to claim 6, characterized in that the active part (2) is fixed to the feed-through conductor (16). 7. Surge arrester (1) according to claim 6, characterized in that the closure (8), the feed-through (15) and the active part (2) form a preassembly unit outside the housing (3).

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