EP1519395B1 - Interrupting chamber - Google Patents

Description

The invention relates to a switching chamber or quenching chamber for a circuit breaker, in particular for high voltage systems according to the preamble of the main claim, as disclosed in EP 0 513 945 A1 , The invention further relates to a circuit breaker with such a switching chamber.

In high-voltage system switches are regularly, in particular to allow a small-volume design of circuit breakers, switching chambers or extinguishing chambers used, which include a resulting in a switching arc that is deleted there. Such switching chambers have an insulation gap that must hold a voltage applied to the circuit breaker with the circuit breaker open. This isolation path is bridged by an isolation region of a wall of the corresponding switching chamber, which is manufactured there from a non-conductive material. In the closed state of a conventional circuit breaker with such a switching chamber, the switching chamber takes on a pin-like and along a switch axis displaceable switching piece, which can be accommodated at one end of a ring or tulip contact as a second switching piece.

Such switching chambers and circuit breakers have the disadvantage that during switching operations, which are accompanied by switching arcs, hot burned material can be thrown onto the wall of the switching chamber, even in the isolation area. This burn-off material, which usually also consists of metallic Abbrandteilchen, can be spread over large areas of the wall of the switching chamber, which brings a weakened isolation capability with it. Also, in switching operations, charges can be induced on surfaces of the wall in wide ranges, whereby an electric field in the switching chamber and thus a behavior of a Switching arc can be influenced, which make it difficult to delete the switching arc and the isolation of the circuit breaker in the open state, at least after a larger number of switching operations can further weaken. To compensate for these disadvantages, it is necessary in the prior art to choose relatively large dimensions for the switching chamber, so both a relatively large length to ensure a sufficiently long isolation distance, as well as a large radial distance between rated contacts of the circuit breaker and the Wall of the switching chamber in the isolation area to minimize deposition of burn-off material. Of course, the required dimensions are dependent on the voltage to be held. In any case, but obtained by switching chambers and circuit breakers with an undesirable large space and material requirements.

The invention is therefore based on the object to develop a switching chamber and a corresponding circuit breaker with which the disadvantages mentioned can be minimized and allow a construction with smaller dimensions for a given voltage to be held.

This object is achieved by a switching chamber with the characterizing features of the main claim in conjunction with the features of the preamble of the main claim and by a circuit breaker having the features of claim 14. Advantageous embodiments of the invention will become apparent with the features of the dependent claims.

Characterized in that the wall in the isolation region has at least one recess or recess, thus shaped and arranged so that each projection of the switch axis on the wall cuts at least such a recess, one first reaches an extension of the insulation distance with constant dimensions, ie an extension of a shortest, the non-conductive material of the wall in the isolation area not leaving connection between two poles of the corresponding circuit breaker. It should be noted that this material has a more critical effect on the isolation capability of the circuit breaker as a switching chamber filling, usually gaseous extinguishing medium, reinforced even by the possibility of deposition of burned material. Another advantage of the proposed switching chamber is the fact that now fewer burn-off material can settle on this wall through the recesses in the wall of the switching chamber. In addition to the resulting reduced weakening of the insulating capacity of the wall in the isolation area, this also provides an advantageous reduction in the influence of such deposits on an electric field and thus an arc in the switching chamber. Finally, a relatively small design of the switching chamber and a circuit breaker, which contains such a switching chamber, can be realized.

In expedient embodiments of the invention, the switching chamber has a cylindrical shape, at least in the isolation region. In particular, when the switching pieces are arranged in the switch axis or symmetrically to the switch axis, this results optimally minimized dimensions at a given minimum distance of the wall of the switching chamber in the isolation area to live parts of the corresponding circuit breaker.

In order to enable a sufficiently stable construction of the switching chamber, such embodiments are preferred in which the wall in the isolation region has at least two, better still more than two such recesses. A reasonable manufacturing effort results when no more than twelve such recesses are provided. In an expedient, sufficiently stable and not too complicated embodiment of the invention, the wall will have between five and eight such recesses.

So that each projection of the switch axis on the wall intersects at least one such recess, it is advantageous if the individual recess is elongated and preferably has a length to width ratio of between 4: 1 and 30: 1. Such a recess, which is sufficiently long to effect an effective lengthening of the insulation gap, and at the same time sufficiently wide to avoid penetration through the recess, forms a slit with a length to width ratio of between, in optimized embodiments of the invention 9: 1 and 20: 1. A slot-shaped recess can be shaped in a particularly simple manner so that two opposite edges of the recess are parallel.

With recesses formed by slots, an extension of the isolation path and the feature that each projection of the switch axis on the wall intersects at least one recess can be achieved by inclining the slots with respect to the switch axis. Preferably, the slots are to run more than 20 °, better still for a larger effect at least 30 °, with respect to the switch axis or a projection of the switch axis on the wall at a location defined by the corresponding slot inclined. It is advantageous to arrange at least two, better still more than two such recesses parallel next to each other, preferably equidistant, so that the recesses form a thread-like structure. A higher number of slots facilitates an extension of the isolation distance and a reduction for deposits of vulnerable surfaces in avoiding too large stability losses. To avoid excessive loss of stability of the switching chamber, however, a slot designed as a slot should then have a slope of not more than 45 °, the exact slope can be selected depending on the desired extension of the isolation distance.

In another embodiment of the invention, slot-shaped recesses in the wall of the switching chamber can also be oriented perpendicular to the switch axis, wherein the recesses must then be arranged laterally offset in at least two rows, to force an extension of the shortest isolation distance in the wall.

Switching chambers according to the invention can be designed with smaller dimensions than corresponding switch chambers according to the prior art. The exact dimensions will depend on the voltage to be bridged and on expected currents during switching operations; in practical embodiments of the invention for applications in which the advantages mentioned are particularly pronounced, the isolation range will be between 100 mm and 250 mm, especially when used in such switches designed for a nominal voltage of between 72.5 kV and 550 kV. Also, especially for use in such switches, the switching chamber is preferably at least in the isolation range with a diameter of between 150 mm and 300 mm run to the smallest possible dimensions of the switching chamber and the corresponding switch with the largest possible distance of the wall of the switch chamber to a switching arc connect. The recesses can with appropriate switches a maximum extent, in slot-like recesses so a length of between 50 mm and 300 mm in order to save the largest possible area and to effect the largest possible extension of the isolation distance with the lowest possible stability losses for the switching chamber.

The switching chamber, which is to be made in the isolation of a very good insulating material, there may consist of cast resin or a fiber-reinforced resin, a material with which recesses can be implemented particularly well while avoiding frayed edges. Suitable fiber materials are industrial products such as Trevira or Kevlar in question. Preferably, a wall thickness of between 4 mm and 15 mm is provided for the wall of the switching chamber in the isolation region to ensure a sufficiently high stability with the lowest possible cost of materials.

A switching chamber according to the invention is particularly well suited for a circuit breaker which uses a gas as an extinguishing agent, wherein the extinguishing chamber in any case must not hold any liquid in a manner that would not be compatible with recesses in the wall of the switching chamber. In a typical embodiment of a circuit breaker according to the invention, in particular a circuit breaker for high voltage systems, with a switching chamber of the type described, a pin-like contact piece is slidably disposed in the switch axis, which is surrounded by the quenching chamber with the circuit breaker closed and to lie in a ring or tulip contact as rated current contact comes, wherein preferably an additional, lying on the switch axis arc contact is provided, to which a switching arc can skip to protect the corresponding rated current contact.

Figur 1

einen Querschnitt durch eine erfindungsgemäße Schaltkammer,

Figur 2

eine perspektivische Ansicht der Schaltkammer aus Figur 1 und

Figur 3

ebenfalls in perspektivischer Darstellung eine Ansicht einer weiteren erfindungsgemäßen Schaltkammer.

Embodiments of the invention are described below with reference to the Figures 1-3 explained. It shows

FIG. 1

a cross section through a switching chamber according to the invention,

FIG. 2

a perspective view of the switching chamber FIG. 1 and

FIG. 3

also in perspective a view of another switching chamber according to the invention.

In FIG. 1 So is a section of a switching chamber of substantially cylindrical shape shown. The switching chamber has a cylindrical center piece 1, which forms an isolation region of the switching chamber. At two ends 2 this Middle piece 1, which is made of a Trevira casting resin, each followed by a metallic continuation piece 3, which includes the corresponding end 2 of the center piece 1. The middle piece 1 forms a wall of the switching chamber in the isolation region, which has a wall thickness of 5 mm there. In the isolation region, this wall has six recesses 4 which are formed as slots and which are inclined by approximately 30 ° relative to a switch axis 5 defined as the axis of symmetry of the switching chamber. These recesses 4 have a length of about 151 mm and a width of about 25 mm. The isolation region of the switching chamber, in contrast, has a length of 200 mm bridged by the center piece 1 and defined as the shortest distance between the metallic continuation pieces 3, with a diameter of the switching chamber in the isolation region of 240 mm. The recesses 6 are arranged equidistantly parallel next to each other, so that they form a thread-like structure and each projection of the switch axis 5 on the wall formed by the middle piece 1 at least one of the recesses 4 intersects. This results in an extended insulation distance, ie an extended shortest connection between the continuation pieces 3 within the wall of the insulating center piece 1, as well as a reduction of a surface formed by this wall at which Abbrandteilchen could be deposited due to a switching arc.

The described switching chamber or quenching chamber is in FIG. 2 once again shown in perspective, with identical features are again provided with the same reference numerals. This switching chamber is intended for installation in a circuit-breaker for a high-voltage system with a rated voltage of 245 kV, which uses a gas as an extinguishing agent. A pin-like contact piece of this circuit breaker then comes to rest in this here no longer specifically marked switch axis 5, along which it is designed to be displaceable, so that it is surrounded by the illustrated switching chamber when the switch is closed. A tulip contact, the said contact piece when closed Power switch receives, which serves as a rated current contact and in the middle of an additional arcing contact is arranged, then finds its place at one end of the switching chamber.

Another embodiment of a switching chamber according to the invention is in FIG. 3 shown, with recurring features are again identified by the same reference numerals. Unlike the embodiment described above, the recesses 4, which are again designed here as slots, arranged with a direction perpendicular to the switch axis 5 orientation. The fact that the recesses are arranged in two rows and offset, it is again ensured that each projection of the switch axis 5 on the wall of the center piece 1 intersects at least one of the recesses 4, the recesses 4 thus have an extended isolation distance result.

Claims (16)

1. Interrupting chamber for a circuit breaker with a wall surrounding a switch axis, this wall being manufactured from a nonconductive material in an insulation region, characterized in that the wall has at least one cutout (4) in the insulation region such that each projection of the switch axis (5) onto the wall intersects at least one such cutout (4).
2. Interrupting chamber according to Claim 1, characterized in that it has a cylindrical form at least in the insulation region.
3. Interrupting chamber according to either of Claims 1 and 2, characterized in that the wall has at least two, preferably between 3 and 12, such cutouts (4) in the insulation region.
4. Interrupting chamber according to one of Claims 1 to 3, characterized in that the wall has between 5 and 8 such cutouts (4).
5. Interrupting chamber according to one of Claims 1 to 4, characterized in that the cutout (4) has a ratio of the length to the width of between 4:1 and 30:1, preferably between 9:1 and 20:1.
6. Interrupting chamber according to one of Claims 1 to 5, characterized in that the cutout (4) forms a slot with two edges which are positioned opposite and parallel to one another.
7. Interrupting chamber according to one of Claims 1 to 6, characterized in that the cutout (4) forms a slot, which is inclined with respect to the switch axis through at least 20°, preferably between 30° and 45°.
8. Interrupting chamber according to Claim 7, characterized in that two or more such cutouts are arranged parallel next to one another, preferably equidistantly.
9. Interrupting chamber according to one of Claims 1 to 6, characterized in that two or more such cutouts (4) are provided as slots with a perpendicular orientation with respect to the switch axis.
10. Interrupting chamber according to one of Claims 1 to 9, characterized in that the insulation region has a length of between 100 mm and 250 mm.
11. Interrupting chamber according to one of Claims 1 to 10, characterized in that the cutout (4) has a maximum extent of between 50 mm and 300 mm.
12. Interrupting chamber according to one of Claims 1 to 11, characterized in that it has a diameter of between 150 mm and 300 mm at least in the insulation region.
13. Interrupting chamber according to one of Claims 1 to 12, characterized in that it is manufactured from cast resin or from a fibre-reinforced cast resin in the insulation region.
14. Circuit breaker containing an interrupting chamber according to one of Claims 1 to 13.
15. Circuit breaker according to Claim 14, characterized in that it contains a gas as quenching medium.
16. Circuit breaker according to either of Claims 14 and 15, characterized in that a ring contact or tulip contact is arranged at one end of the quenching chamber, and preferably an additional arcing contact or central arcing contact integrated in said ring or tulip contact.

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