EP2713375A1 - Surge absorbers - Google Patents

Abstract

The arrestor (1) has a control cover (3) electrically connected to a diversion element (2), where the diversion element comprises an earth contact (5) and a high-voltage contact (6) electrically connecting an interior of a fluid-tight housing (4) to an exterior. The control cover comprises two partial covers (10, 11), which are electrically connected to one another and movable relative to one another such that an electrical connection from the earth contact to the high-voltage contact is established or interrupted via the diversion element.

Description

The invention relates to a surge arrester according to the preamble of patent claim 1.

Surge arresters are protective systems, for example, for switchgear, which in case of overvoltages caused by lightning or malfunction of other subsystems derive these surges towards the ground and protect other components of the switchgear.

Such a surge arrester comprises one or more cylindrical diverting elements, which have a varistor column made up of individual, likewise cylindrical varistor elements. Varistor elements are characterized by a voltage-dependent resistance. At low voltages these act as insulators. From a certain threshold voltage, which is material-dependent, they show a good conductivity. Frequently, varistor elements are made of metal oxides such as zinc oxide. The diverter is limited at both ends by end fittings that make electrical contact with the switchgear and ground. To ensure a good electrical contact even under mechanical stress, the varistor column must be held together under pressure. This can be done by tension members, for example, ropes or rods are preferably clamped in glass fiber reinforced plastic in the end fittings under train. The tension elements surround the varistor column and thus form a cage around them.

For use in gas-insulated switchgear surge arresters have a fluid-tight housing, which surrounds the discharge element. The housing is to increase the dielectric strength with a fluid, usually sulfur hexafluoride, filled. The housing is usually made of metal and is electrically grounded. An end fitting of the Ableitsäule is over grounded through a contact led by the housing. The other end fitting is electrically connected via a passage with a contact located on the outside of the housing, which serves to connect to the switchgear. In particular, larger surge arresters often have at their high voltage end of a control hood, which is slipped over the end of the Ableitsäule as unilaterally closed cylinder. The individual varistor elements have a high capacitance with respect to ground potential, but their series connection leads to a very small longitudinal capacitance, which leads to an inhomogeneous voltage distribution as of a certain length of the varistor column. In part of the varistor column, which is further away from the ground potential, the varistor elements are therefore subject to higher voltages, which together with their resistive effect can lead to undesired heating. The control hood now serves to homogenize the stress distribution along the length of the varistor column.

If the switchgear is to be electrically tested, then the surge arrester must be disconnected from the switchgear because of the high voltages which then occur. Otherwise, the surge arrester would divert the voltage to ground and the measurement result would be corrupted.

So far surge arresters are known which have a separation point, whereby the surge arrester can be separated from the switchgear. To actuate this separation point, the housing must be opened, whereby sulfur hexafluoride can escape. Since sulfur hexafluoride is a harmful greenhouse gas, this is highly undesirable and thus detrimental.

From the JP 10322822-A a generic surge arrester is known in which the Ableitsäule is separated from the switchgear by the arrangement of the delivery column and the control hood is moved together and so an electrical connection is made or interrupted. For operation In this case, a linear movement is performed gas-tight through the housing wall.

In the international application with the registration file PCT / EP2012 / 059973 a surge arrester is described in which the control hood are moved against the discharge element and so a separation point can be opened or closed.

A disadvantage of the prior art is that relatively large masses must be moved. Object of the present invention is to provide a surge arrester, which manages with a smaller mass to be moved.

The object is achieved with the means of the invention according to claim 1.

Accordingly, a surge arrester has a diverting element, a control hood electrically connected to the diverting element and a fluid-tight housing in which the diverting element and the control hood are arranged. The housing has a ground contact and a high voltage contact, wherein the ground contact and the high voltage contact each electrically connect the interior with the exterior of the housing. According to the invention, the control hood has a first partial hood and a second partial hood, wherein the first partial hood and the second partial hood are electrically connected to one another and displaceable relative to one another such that an electrical connection from the ground contact to the high-voltage contact can be produced or interrupted via the diverting element. Thus, one of the partial hoods can be fixed, and only the other be designed to be movable, which reduces the moving mass.

In an advantageous embodiment of the invention, the first and the second part hood are cylindrical and telescopically slidable. As a result, a good axial guidance is given.

The first partial hood is preferably connected to a high-voltage-side end fitting of the diverting element, and the second partial hood can be displaced against the first in an axial direction of the diverting element. Since the first part hood is immovable, it can thus be optimally adapted to the task of field control. The second, movable part of the hood assumes the function of opening or closing the contact by being displaceable against the first part of the hood in the axial direction of the diverter and can be brought into contact with the high voltage contact to close the contact or vice versa.

Furthermore, it is preferred that the second partial hood has on its front side a recess which can be brought into a flat contact with a correspondingly shaped recess on the high-voltage contact by the projection dipping into the recess. The second partial hood could for example have a recess with a concave contour, and the high voltage contact a bulge with a convex contour. Preferably, the contours are rotationally symmetrical about the axial direction of the discharge element. The contour could be spherical or conical. It is also conceivable that one of the contours cone-like, the other is spherical. When moving the second part of the hood in the direction of the high voltage contact, the bulge will dive into the depression from a certain distance from each other. Touch the second part of the hood and the high voltage contact, so there is a flat contact point, which allows a particularly good contact. If one of the contours is cone-like, the other is spherical, an annular contact surface results due to the finite hardness of the materials. In any case, such a separation point is self-centering, so tolerant to small deviations of the displacement direction from the axial direction.

Figur 1

einen erfindungsgemäßen Überspannungsableiter mit geöffneter Trennstelle,

Figur 2

einen erfindungsgemäßen Überspannungsableiter mit geschlossener Trennstelle,

Figur 3

den Bereich um die hochspannungsseitige Endarmatur eines erfindungsgemäßen Überspannungsableiters.

In the following the invention will be explained in more detail with reference to the drawings. Showing:

FIG. 1

a surge arrester according to the invention with opened separation point,

FIG. 2

a surge arrester according to the invention with closed separation point,

FIG. 3

the area around the high-voltage side end fitting of a surge arrester according to the invention.

Corresponding parts are provided in all figures with the same reference numerals.

The FIG. 1 shows a surge arrester 1 according to the invention with open separation point 17. The surge arrester 1 in this case has a gas-tight housing 4. The housing 4 is shown here cut open in all figures for clarity. The housing 4 is cylindrical and closed on one side with a housing cover 16. The housing 4 is usually filled in the ready state with an insulating fluid such as sulfur hexafluoride under pressure. Through the housing cover 16 is not visible here a ground contact 5 an electrical connection from the outside into the interior of the housing 4. The electrical connection can be made for example by an electrically conductive cover 16, or by an electrically insulated against the cover implementation as in the EP 12 170 022.3 described, be prepared. On the cover 16 opposite end of the housing 4, a high-voltage contact 6 is arranged, which is shown here as a high-voltage bushing. This high voltage bushing provides a suitable electrical connection, insulated against the housing 4, for high voltages of one kilovolt to several hundred kilovolts, depending on the application.

Inside the housing 4, a discharge element 2 is arranged. This has a cylindrical Varistorsäule 7, a low-side end fitting 8, a high-voltage side end fitting 9, which is not visible here, and several tension elements 14 on. The varistor column 7 is composed of individual, also cylindrical Varistorblöcken. The end fittings 8, 9 are usually made of electrically conductive material. Tension elements 14 are pressed in the end fittings 8, 9 under train and thus hold the varistor column 7 together. In the varistor column 7 retaining disks may be inserted, having holes through which the tension members 14 are guided and thus stabilize the discharge element 2 in addition. The longitudinal axis 18 of the varistor column determines an axial direction.

On a ground terminal side of the discharge element 2, the top surface of the housing 4 is closed with a simple housing cover 16. A ground contact 5 is electrically insulated by this housing cover 16 from the inside to the outside of the housing 4 and serves the ground terminal. Inside the housing 4, this ground contact 5 is electrically connected to the diverting element 2, for example with a cable. The earth-side end fitting 8 of the discharge element 2 is fastened to the housing cover 16. The housing cover 16 is electrically insulated from the varistor column 7. As a rule, the housing cover 16 has a connection, not illustrated here, via which fluid, for example sulfur hexafluoride, can be introduced into the housing 4 or drained off.

On a high voltage terminal side of the discharge element 2, the top surface of the housing 4 is provided with a designed as a high voltage feedthrough high voltage contact 6 to lead the electrical high voltage potential without risk of a rollover between high voltage and grounded housing 4 from the outside into the housing 4 into it.

A substantially cylindrical control hood 3 is slipped over the high-voltage side end of the diverting element 2. The control hood 3 consists of a first partial hood 10 and a second partial hood 11. The two partial hoods are telescoped into one another. The second part hood 11 is connected to a displacement device 15, which is shown here as a push rod. The displacement device 15 is guided in a fluid-tight manner through the housing cover 16 and permits operation of the separation point from outside the housing 4. With the displacement device 15, an operator can move the second part hood 11 in the axial direction toward the high-voltage contact 6, without opening the housing 4 until the separation point 17 is finally closed, as in FIG. 2 shown. Thus, an electrical connection from the high-voltage contact 6 via the second part hood 11, the first part hood 10, the high-voltage side end fitting 9, the varistor column 7, the ground-side end fitting 8 to ground contact 5 is made. If the second partial hood 11 is moved in the opposite direction, ie away from the high-voltage contact 6, then the separating point 17 and thus the electrical connection is opened.

In order to ensure a good contact between the high-voltage contact 6 and the second partial hood 11, the partial hood 11 is provided on its front side with a ball-like depression 12, which is exemplified here. A bulge 13 of the high-voltage contact 6, which is likewise shown as a ball, emerges into the depression 12 until finally contact between the second partial hood 11 and the high-voltage contact 6 has been established. The axes of the spherical bulge 13 or recess 12 are centered with each other, so that tolerances of the displacement direction can be compensated.

In FIG. 3 the high-voltage side end of the diverter element 2 is shown with the control hood 3. The control hood 3 is here shown cut open to show the high-voltage side end fitting 9. First part hood 10 and second part hood 11 are telescopically pushed together here. In this case, the second part of the hood 11 lies outside the first part of the hood 10. Inside the control hood 3, the high-voltage side end fitting 9 is visible. The tension elements 14 are pressed with this. The displacement member 15 is a push rod passing through an opening in the high voltage side Endarmatur 9 out and connected to the second part of the hood 11 at the end face. The first part hood 10 is a cylinder open on both sides, which has a thickening at the lower edge in order to avoid field line compression there. It is also firmly connected to the high-voltage side end fitting 9. Between the first part of the hood 10 and the second part of the hood 11, sliding elements, not shown here may be arranged to reduce the friction and to ensure good management. The second part hood 11 is displaceable by means of the displacement device 15 against the first part hood 10 in the direction of the longitudinal axis 18. An electrical connection between the first partial hood 10 and the second partial hood 11 can be produced, for example, by means of a flexible current band.

Claims (4)

Surge arrester (1) having a diverting element (2), a control hood (3) electrically connected to the diverting element (2) and a fluid-tight housing (4), in which the diverting element (2) and the control hood (3) are arranged and which one Earth contact (5) and a high voltage contact (6), wherein the ground contact and the high voltage contact each electrically connect the interior with the exterior of the housing (4),
characterized in that the control hood (3) has a first partial hood (10) and a second partial hood (11), wherein the first partial hood (10) and the second partial hood (11) are electrically connected to one another and displaceable relative to one another, that an electrical Connection from the earth contact (5) to the high voltage contact (6) via the discharge element (2) can be produced or interrupted. Surge arrester (1) according to claim 1,
characterized in that the first and the second partial hood (10, 11) are cylindrical and are telescopically slidable. Surge arrester (1) according to one of Claims 1 or 2,
characterized in that the first part hood (10) is connected to a high-voltage side end fitting (9) of the diverting element (2), and that the second divisional hood (11) is displaceable against the first one (10) in an axial direction of the diverting element (2) , Surge arrester (1) according to one of Claims 1 to 3,
characterized in that the second part hood (11) has on its front side a recess (12) which with a correspondingly shaped bulge (13) on the high voltage contact (6) in a flat Contact can be brought by the bulge (13) dips into the recess (12).

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