KR20150135486A - Encapsulated surge arrester - Google Patents

Abstract

The present invention relates to a surge arrester (1) having a fluid-tight housing (2) and an active part (6) for overvoltage discharge arranged in the housing (2). The active part 6 comprises discharge elements 8 arranged in the stacks 7 and a plurality of stacks 7 arranged in a stacked manner and separated from each other by an intermediate insulating member 9, (10). The active section 6 has several columns 10 of this type in which the stack 7 of adjacent columns 10 is arranged such that the current path 11 passes through the active section 6 in the form of a meandering So that they are electrically connected to each other. According to the present invention, the columns 10 are arranged side-by-side in a row. This surge arrester 1 has a very compact dimension, which is very well adapted to the narrow space conditions inside the high voltage switchgear.

Description

{ENCAPSULATED SURGE ARRESTER}

The present invention relates to a surge arrester sealed by a fluid-tight housing according to the preamble of claim 1.

Surge arrester is a protection system, for example a switchgear, which protects other components of the switchgear by discharging such overvoltage to ground when an overvoltage occurs due to a lightning or other subsystem malfunction.

This type of surge arrester includes one or more active portions having varistor columns comprised of cylindrical, individual varistor elements. The varistor element has a characteristic that the resistance depends on the voltage. When the voltage is low, the varistor element acts as an insulator. From the specific threshold voltage depending on the material, the varistor element exhibits good conductivity. The varistor element is mainly made from a metal oxide such as zinc oxide. The discharge element is limited at both ends by the end fixture forming electrical contacts to the switchgear and ground. The varistor columns should be pressed together to ensure good electrical contact under mechanical load. This can be realized, for example, by tensioning elements of a glass fiber-reinforced plastic material, such as a pipe, cable or rod, clamped into the end fixtures in a tensioned state. In this case, tensile elements surround the varistor column.

For use in a gas insulated switchgear, the surge arrester has a sealed fluid-tight housing surrounding the discharge element. In this case, the housing is filled with a fluid, usually Sulfur Hexafluoride, to increase the dielectric strength. The housing is formed of a conductive material, for example a metal, and is electrically grounded. One end fixed body of the discharge column is grounded by a contact formed through the housing. The other end fixed body is located outside the housing and electrically connected to the contact used for connection to the switch through the feedthrough.

Surge arresters of this type are known, for example, from DE 102011077394 Al. In this document a single columnar active portion is disposed within the fluid-tight housing. However, in the case of high voltage, the active part can be extended to several meters.

From US 4814936 Al, a surge arrester having an active part consisting of four columns is known. These columns are arranged in rotational symmetry around the housing axis in one square. In the case of this configuration, the longitudinal extension is shorter than in the cases described above, but the lateral extension requires more configuration space.

SUMMARY OF THE INVENTION The present invention provides a surge arrester that is further optimized for the spatial conditions of the switchgear.

The above problem is solved by means of the present invention according to claim 1.

The surge arrester herein has a fluid-tight housing with a housing wall extending between the bottom cover and the top cover along the housing axis. The surge arrester also has an active part for overvoltage discharge, arranged in the housing and including discharge elements arranged in the stacks, wherein a plurality of stacks arranged in a stacked manner and separated from each other by an intermediate insulating member To form a column. The active portion has a plurality of columns whose longitudinal axes are disposed parallel to the housing axis, wherein the stack of adjacent columns is electrically connected to each other such that the electric current path is guided through the active portion in a meandering fashion. This connection may be carried out, for example, through a cable or conductive strip disposed on the outer surface of the discharge elements, preferably between two stacks of adjacent two columns and respective intermediate members abutting these stacks, Lt; RTI ID = 0.0 > electrically < / RTI > According to the invention, the columns are arranged side-by-side in a row. The surge arrester according to the present invention is certainly shorter than a surge arrester having a single column active portion. The surge arrester according to the present invention is narrower in width than the surge arrester in which the columns of the active portion are arranged in a rectangular shape because the columns are arranged side by side. It is rare to have the same wide space in all directions in the switchgear. The surge arrester according to the present invention is oriented in the switch so that the narrower side faces in the direction in which the narrower space is provided.

In one preferred configuration, the housing wall has an elliptical cross-sectional profile with a long axis and a short axis in one section along the housing axis, and the rows of columns are arranged along a long axis. The elliptical housing has a high compression strength while optimally matching the tandem arrangement of the columns.

Also preferably, the intermediate members are arranged at the same height of the column in the adjacent columns, and a connecting element is arranged between the intermediate member and the stacks touching both sides of the intermediate member, ≪ / RTI > to the stack of adjacent columns. With this arrangement, two electrical connections for a stack of adjacent columns can be formed for one intermediate member. As a result, the intermediate members can be saved and the column can be made shorter.

In another preferred construction, the intermediate member of the one column and the intermediate member of the adjacent column arranged at the same height are formed as the ends of the integral support plate. As such, the intermediate members can be used as additional mechanical connections between the adjacent two columns, which improves the mechanical stability of the active portion.

In addition, in one preferred configuration of the present invention, the connecting elements are the layers provided on the upper and lower surfaces of the support plate. Thereby, only one member can be handled in place of the three members, so that the assembly is simplified.

BRIEF DESCRIPTION OF THE DRAWINGS Fig.

1 is a longitudinal sectional view of a surge arrester according to the present invention.
Fig. 2 is a plan view of the surge arrester of Fig. 1. Fig.

The members corresponding to each other are given the same reference numerals in all drawings. Reference numerals having additional characters denote similar elements. Where reference numerals are used without additional characters, they mean all corresponding components.

1 is a longitudinal sectional view of a surge arrester 1 according to the present invention. 2 is a plan view of the same surge arrester 1. The columns 10a, 10b and 10c of the active part 6 are here shown so as to be seen through the cover 5. The surge arrester (1) has a fluid-tight housing (2) which is usually formed of a conductive material and electrically grounded. The housing (2) has a lower cover (4) and an upper cover (5). Between the covers 4 and 5, the housing wall 3 extends along the housing axis 30. The housing is filled with an insulating fluid such as oil or sulfur hexafluoride, ready for operation. An active part (6) used for overvoltage discharge is disposed in the housing (2). The active portion 6 is limited by the top fixing body 20 at the high voltage side end 26. The upper fixed body is electrically connected to the high voltage contact 16 and the high voltage contact again guides the electrical connection to the outside through the upper cover 5 through the high voltage feedthrough 25. [ Outside the housing 2, the connection to the high voltage switch not shown here can be realized by the electrical connection. At the ground-side end portion 27 of the active portion 6, the active portion is limited by the lower end fixed body 21, wherein the lower end fixed body is shown as three parts. However, the integral end fixture 21 may also be possible. The lower fixture 21 can be formed of an electrically conductive material, in which case the ground connection can be guided out of the active section 6 through the lower fixture 21 and the lower cover 4. Outside the housing 2, the ground connection may be grounded. Alternatively, the lower fixture 21 may be formed to be electrically insulated. In this case, the active part 6 is fluid-sealed and electrically insulated with respect to the lower cover 4, and can be connected to ground outside the housing 2 via a grounding contact, not shown here. Normally, the active portion 6 is gripped by a tension element not shown here. The tension elements are arranged around the active part in the form of a cage or enclose the active part as individual tension elements in the form of a conduit. The tension element (s) is clamped within the upper fixture 20 on one side and the lower fixture 21 or lower cover 4 on the other side to grip the active portion.

The active part 6 here comprises three columns 10a, 10b and 10c. Alternative assemblies consisting of two, four or more columns 10 may also be possible. Preferably, the surge arrester according to the present invention has an active portion 6 composed of three or more columns 10. These columns 10 each extend along a longitudinal axis 31 which is parallel to the housing axis 30 and are arranged side by side in a row. Two outer columns 10a and 10c are disposed on the side of one inner column 10b. These columns 10 each consist of a plurality of discharge element 8 stacks 7. The stacks 7 are separated from each other by an intermediate insulating member 9. In the drawing, discharge elements 8 are merely illustrative but are generally formed of one disc-shaped varistor block. The above structure will be described in detail using the column 10a as an example. The column 10a is constituted by a total of 18 discharge elements 8 which are stacked on each other in four stacks 7a, 7b, 7c and 7d, in which the stack 7a is divided into three discharge elements 8), and the stacks 7b, 7c, 7d each include five discharge elements. The four stacks 7a, 7b, 7c and 7d are separated from each other by three intermediate insulating members 9a, 9b and 9c, and are electrically insulated from each other in one column. The intermediate member 9b separates, for example, the stacks 7b and 7c from each other and insulates them from each other. At the ground side end portion 27 of the active portion 6, the stack 7d is contacted with an intermediate member 9d which insulates the stack 7d with respect to the end fixing body 21 and terminates the column. The columns 10b and 10c are similarly formed when the number of the stack 7, the discharge element 8 and the intermediate member 9 are different from each other. Preferably, the outer columns 10a, 10c are formed in the same way, but arranged rotationally symmetrically. The inner column 10b or the stack 7 of inner columns 10 includes the same number of, here two, discharge elements 8 in the preferred embodiment shown here. In one preferred embodiment of this embodiment the inner column 10b comprises only a stack 7 with n discharge elements and the outer columns 10a and 10c comprise a stack 7 with 2n + , And each stack having n + 1 discharge elements 8 terminates one side of the outer columns 10a, 10c.

One connecting element 9 is disposed between one stack 7 and the adjacent intermediate member 9, respectively. The connecting element 9 electrically connects two stacks 7 of adjacent columns 10 to each other. Thus, for example, in the column 10a, one connecting element 14c is disposed between the stack 7c and the intermediate member 9b adjacent thereto. This connecting element 14c is guided from the column 10a to the inside of the column 10b which is perpendicular to the longitudinal axis 31 and between the stack 7i and the adjacent intermediate member 9f in the adjacent column . That is, the connecting element 14c connects the columns 10a and 10b at the same height. An electrical connection is formed between the stacks 7c and 7i. Thereby, the stacks 7c and 7i are connected in series. That is, the current path 11 through the column 10a is here cut off by the intermediate electrical insulating member 9c and led through the column 10b. The current path 11 through the active part 6 starts from the upper fixing body 20 and is guided through the stack 7a of the column 10a continuously in the direction of the ground side end 27, Is led into the stack 7e of the column 10b through the connecting element 14a and is then guided in the direction of the high voltage side end 26 through the connecting element 14d into the stack 7g of the column 10c Where it proceeds again in the direction of the ground side end portion 27 and finally through the connecting element 14e in the reverse direction through the stack 7f and the connecting element 14b into the stack 7c of the column 10a . In a similar manner, the current path 11 is guided to the stack 7h of the column 10c through the entire active portion 6 and finally through the stacks 7 connected in series to each other in a meandering manner. Where the current path is guided outwardly from the housing 2 via the lower fixture 21 or the ground contact as described above. For convenience of illustration, horizontal connecting lines of the current path 11 are shown beside the connecting elements 14. In practice, the current flow in the current path 11 naturally extends through the connecting elements 14.

At two points, the intermediate members are formed as the ends of the integral support plates 15a, 15b. That is, the intermediate members of two adjacent columns are combined to form one integral support plate 15a, 15b. An intermediate member between the stacks 7c and 7d of the column 10a is combined with an intermediate member between the stacks 7j and 7k of the column 10b to form one support plate 15a. The support plate 15a is used to increase the mechanical stability of the active portion 6 by connecting the columns 10a and 10b at the same height, respectively. The intermediate member 9 and the support plate 15 may be made of a material such as, for example, epoxy resin, casting resin or other electrically insulating solids. The description of the intermediate member 9 is hereinafter also applied to the support plate 15 even when the support plate 15 is not specified.

All of the intermediate members 9 to the intermediate member 9 located at the end of the stack 10 are provided with an intermediate member 9 and stacks 7 which are in contact with both sides of the intermediate member, One connecting element 14 is arranged. That is, for each of these intermediate members 9, two electrical connections to adjacent columns 10 are formed. The intermediate members 9 and the connecting elements 14 are dimensionally designed so that the columns 10 have the same height even when the number of the intermediate members 9 and the stacks 7 are different. Inside the column 10 in which one intermediate member 9 and two connecting elements 14 are disposed between two stacks 7 of one column 10, one intermediate member 9 The total thickness of the two connecting elements 14 corresponds to the thickness of one discharge element 8. [ At the ends of the column 10, the total thickness of one intermediate member 9 and one connecting element 14 corresponds to the thickness of one discharge element. The connecting elements 14 may be a thin metal plate or a metal layer provided on the upper and lower surfaces of the support plate 15 in the case of the support plate 15.

The housing wall 3 has an elliptical cross-sectional profile over a section 17 along the housing axis 30, and the elliptical shape includes an egg shape as well as an elliptical shape. At this time, the housing 2 has a long axis 12 and a short axis 13, and the long axis 12 is longer than the short axis 13. The rows of columns 10 are arranged along a long axis 12.

In addition, the housing 2 may have an adapter 22 that can be closed by a manhole cover 23. A vent which is closed by the membrane can be arranged in the manhole cover, which is damaged when the pressure in the housing 2 due to the defect rises and discharges the pressure to the outside. The resulting fluid flow can be diverted through the discharge hood 24 in a direction that can not adversely affect other system members.

Claims (5)

A housing wall 3 extending along the housing axis 30 between the lower cover 4 and the upper cover 5 and discharge elements arranged in the housing 2 and arranged inside the stacks 7 A surge arrester (1) having a fluid-tight housing (2) having an active part (6) for overvoltage discharge, comprising a plurality of electrodes A plurality of stacks 7 form one column 10 and the active section 6 has a plurality of columns 10 whose longitudinal axes 31 are arranged parallel to the housing axis 30, Wherein the stack 7 of adjacent columns 10 is electrically connected to each other such that the current path 11 is guided through the active portion 6 in a serpentine configuration,
Characterized in that the columns (10) are arranged side-by-side in a row. 2. A method according to claim 1 wherein the housing wall has an elliptical cross-sectional profile with a long axis and a short axis in a section of the housing along the housing axis, Characterized in that the heat is arranged along the long axis (12). 3. An apparatus according to claim 1 or 2, characterized in that intermediate members (9) are arranged at the same height in adjacent columns (10) and stacks Characterized in that a connecting element (14) is arranged between the stacks (7) of the columns (10), each connecting one stack (7) of the columns (10) Surge arrester (1). 4. An apparatus according to any one of claims 1 to 3, characterized in that the intermediate member (9) of the one side column (10) and the intermediate member (9) of the adjacent column (10) (1). ≪ / RTI > 5. Surge arrester (1) according to claim 4, characterized in that the connecting elements (14) are layers provided on the upper and lower surfaces of the support plate (15).

Images