CZ2006372A3 - Surge-voltage protector - Google Patents

Abstract

The overvoltage arrester comprises electrodes (1) adapted to conduct overvoltages exceeding a set limit, as well as an interface (2) and an arc chute (3). The electrodes (1) are housed in the interconnecting space (2) leading to the arc chute (3), and are shaped as arc arresters. In the vicinity of the electrodes (1) means for generating a magnetic field are arranged, forming an angle of 60 to 120 degrees with the electrode connection (1). The arc chute (3) is connected to the electrode space (1) by an interconnecting space (2) shaped as a tunnel pair, which extends from the electrodes (1) to the arc chute (3) in parallel and extends from the electrode space (1) in opposite directions.

Description

The surge arrester comprises electrodes (1) adapted to conduct a surge exceeding the set limit, and an interconnecting space (2) and an arc quench (3). The electrodes (1) are housed in the interconnecting space (2) leading to the arc chute (3) and are shaped as arc entrainers. In the vicinity of the electrodes (1), means are provided for generating a magnetic field forming an angle of 60 to 120 degrees with the electrode junction (1). The arc chute (3) is connected to the electrode chamber (1) by an interconnecting chamber (2), shaped as a pair of tunnels, which run from the electrodes (1) to the arc chute (3) in parallel connection and in opposite directions.

CZ 2006 - 372 A3

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Surge arresters

Technical field

The present invention relates to surge arresters which are constructed on the spark gap principle, where a voltage exceeds a certain value causes a discharge between the spark gap electrodes and wherein the subsequent structure of the space in the arrester comprises a shaped space adapted to discharge and eliminate the discharge.

BACKGROUND OF THE INVENTION

At present, surge arresters are known where a spark gap is formed in a confined space where shaped electrodes are inserted. Shaping and positioning of the electrodes are carried out in such a way that the wires connected to the individual electrodes gradually move away from each other and are thus introduced into the arc chute space, where the space is divided by several conductive plates adapted to divide the electric arc into several parts with lower partial stresses, where the arc is no longer maintained and is quenched, which is the basic task of the arc chute. Due to the fact that when the arc arises as a result of a spark leakage between the electrodes of the arrester, an extremely strong and rapid increase in pressure occurs, it is necessary to allow the evacuation of gases, resp. pressure waves, from the electrode space, in order to both help extinguish the arcuate arc and, on the other hand, to protect the casing of the arrester from possible damage or destruction. For the same reason, in the previous embodiments, arresters and / or conductors are usually formed in the housing. in the arc chute housing, relief or exhaust openings which, in the event of an arc, allow gas to escape from the surge arrester. However, such a solution has the disadvantage that the vicinity of the arrester may be influenced or damaged by the arc leakage after the arrester protection action. In the known solutions, environmental protection is achieved by means of a special orientation of the relief holes or by additional screening of objects in the vicinity against the hot gas discharge from the surge arrester. Another solution of closing the arc chute would at least significantly slow the leakage of the pressure wave from the electrode space after the discharge,

In addition to damaging the electrodes and the casing of the arrester, the time during which the undesirable short-circuit current passes through the circuit has increased. In addition to the solutions described above, there are even known constructions of arresters, where a magnetic field is applied to the area in the vicinity of the electrodes. in such a situation as a conductor in a magnetic field, the arc acts in a transverse direction by a force to assist the arc to exit the electrode space. Such force has a predictable direction, in accordance with the laws of physics, but has no predictable orientation due to the uncertainty of the direction of current flow in the discharge. This is the reason why simple transient paths, respectively constructed in a conventional way. tunnels interconnecting the electrode compartments, resp. the spark gap space, with the arc chute space, does not solve the problem in cases where an inappropriate discharge current direction in the discharge between the electrodes would act in the opposite direction to the discharge path or tunnel to discharge the arc chamber. Therefore, in this way it is possible to solve the connection of contacts, for example in DC circuit breakers, where when the current load is disconnected, the current direction in the resulting discharge is always the same and predictably directed, but in the surge arrester design. direction of current passage and thus the previous principle cannot be used without further modifications.

SUMMARY OF THE INVENTION

Said disadvantages are solved to a large extent by a surge arrester according to the present invention, wherein the arrester comprises electrodes adapted to conduct a surge exceeding the set limit, and further comprising a connection space and an arc quenching chamber, the electrodes being housed in the interconnecting space leading to the arc quenching chamber. and are shaped as arc entrainers, and wherein, in the vicinity of the electrodes, means are provided for generating a magnetic field at an angle of 60-120 degrees to the electrode junction, and wherein the principle is that the arc chute is interconnected with the electrode space shaped as a pair of tunnels which are led from the electrodes to the arc chute in parallel connection and which extend from the electrode space in opposite directions to each other. Preferably, the pair of tunnels together with the arc chute form a circular annular passage. It is particularly preferred that at least 30% of the length

The circular annular passage is formed by mutually parallel tunnels directed from the electrode space to the arc chute space. The magnetic field generating means is preferably designed as permanent magnets arranged to generate a magnetic field forming an angle of 80-100 degrees to the electrode junction. Advantageously, for the direct gas outlet of the arc chute, the arc chute appears to be closed. Preferably, relief holes are provided in the arrester housing, in the region of the arc chute, connected to the outside atmosphere via a labyrinth outlet. Finally, it is advantageous if the relief holes have an area corresponding to 1 to 30% of the area of the arc chute housing.

This results in an overvoltage arrester in which, in the event of a discharge, the arc is reliably and quickly secured from the electrodes and the arc is fed into the arc quenching chamber, wherein the entire housing can be closed or possibly have relief holes, but only gas leakage to a very small extent, since the circulation channel and the initial magnetically initiated discharge direction and thus the discharge of the pressure wave from the electrodes in one of the two possible opposite directions, in accordance with physical laws, will never cause the pressure wave from the electrodes proceed against the enclosed space and there will be no significant pressure build-up in any channel or space, since the spaces and channels used are not designed to be a blind arm. In summary, the surge arrester according to the present invention thus achieves both an improvement in functional parameters and an increase in durability and reliability.

Overview of the drawings

The present invention is further described and explained in more detail by way of example, with reference to the accompanying drawings, in which: FIG. 1 shows a partial perspective view of a surge protector; FIG. 2 shows the same surge protector, this time in a longitudinal vertical 3 finally shows the same surge arrester shown here in a longitudinal vertical section, this time in a direction perpendicular to the arc chute plates.

DETAILED DESCRIPTION OF THE INVENTION

The surge arrester is formed in a housing designed in such a way that the arrester can be mounted in conventional rails on distribution boards, etc. The arrester comprises electrodes I adapted for conducting overvoltages exceeding a set limit, and further comprises a connecting space 2 and an arc quench 3, The electrodes 1 are housed in the interconnecting space 2 leading to the arc chute 3 and are shaped as arc entrainers. Around the electrodes 1 there are located means for generating a magnetic field, here in the form of permanent magnets 4. The position of the permanent magnets 4 is selected here such that the direction of the magnetic field forms an angle of 90 degrees with the electrode junction. The arc quenching chamber 3 is connected to the electrode chamber by a connecting space 2, shaped here as a pair of tunnels, which are led from the electrodes 1 to the arc chamber 3 in parallel connection and which extend from the electrode chamber 1 in opposite directions. Preferably, the pair of tunnels embodying the interconnecting space 2 here together with the arc chute 3 in the present exemplary embodiment forms a circular annular passage. If it is generally preferred that at least 30% of the length of the circular annular passage is formed by mutually parallel tunnels directed from the electrode space 1 to the arc chamber 3, then here, in the present exemplary embodiment, form mutually parallel tunnels including also a portion of the arc passage 3, about 80% of the length of the entire circulation annular passage, i.e. the circuit from the electrodes 1 through one tunnel to the arc quenching chamber 3, then through this through arc quenching chamber 3 and through the second tunnel back to the electrodes i. here, the arc chute 3 appears to be closed. This means that either the gas outlet opening is not formed from this arc chute 3 or, if such an opening is formed, it does not allow a direct or non-direct gas outlet. a straight gas outlet, but only an outlet along an exemplary labyrinth track. Advantageously, here, relief holes, not shown in the drawing, are provided in the overvoltage protector housing 10, in the region of the arc chute 3, connecting the space of the arc chute 3 with the outside atmosphere via a labyrinth outlet or a circuit. labyrinth track. The relief openings here have an area corresponding to 2% of the area of the part of the casing 10 covering the arc chute 3. As regards the internal arrangement of the arc chute 3, it is here in a conventional manner, i.e. serially, with respect to the stress input φ φ φ φ φ φ φ φ φ φ φ φ φ φ • φ · · φ φ φ φ φ φ φ φ φ φ φ · · · φ φ φ φ φ φ φ φ φ φ φ · · od od od od od 31. Arranged for arc entry and distribution.

The function of the device is as follows. In the surge arrester, in the event of a discharge, the arc from the electrodes 1 is reliably and quickly discharged and the arc is fed into the arc chute 3. Due to the circulation channel and the initial magnetically initiated discharge discharge direction, the pressure wave leaves the electrodes 1. In opposite directions, in accordance with the laws of physics, the pressure wave from the electrodes 1 will never advance against the enclosed space and there will be no significant pressure increase in any channel or space, here, the ducts, or the arc chute 3, are not formed here with the character of a blind arm. Upon arrival of the arc in the arc chute 3, the arc is quenched in a conventional manner by a transition or a step. In this connection, following the preceding process from the electrodes 1, quenching is particularly fast, reliable and yet gentle to all members exposed to higher pressures and temperatures during the described action. Taken together, the surge arrester according to the present exemplary embodiment achieves both excellent functional parameters and high durability and reliability.

Economic usability

The overvoltage arrester of the present invention is useful for protecting circuits and equipment from accidental overvoltage, particularly the types of overvoltage that may occur due to lightning. However, it can also be used to protect against overvoltage from another source, provided there is some similar voltage and current characteristics.

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PATENT CLAIMS

Claims (7)

What is claimed is: 1. An overvoltage arrester comprising electrodes adapted to conduct overvoltages in excess of a preset limit and further comprising an interconnecting space and an arc quenching chamber, wherein the electrodes are housed in an interconnecting chamber leading to the arc quenching chamber and are shaped as arc arresters; around the electrodes, means are provided for generating a magnetic field forming an angle of 60 to 120 degrees with the electrode junction, characterized in that the arc chute (3) is connected to the electrode space (1) by a communication space (2) shaped as a pair of tunnels are guided from the electrodes (1) to the arc chute (3) in parallel connection and which extend from the electrode chamber (1) in opposite directions to each other. Surge arrester according to claim 1, characterized in that the pair of tunnels together with the arc quenching chamber (3) form a circular annular passage. Surge arrester according to claim 1 and 2, characterized in that at least 30% of the length of the circulation annular passage is formed by mutually parallel tunnels directed from the electrode space (1) to the arc chute space (3). Surge arrester according to Claims 1 to 3, characterized in that the magnetic field generating means are designed as permanent magnets (4) arranged for generating a magnetic field forming an angle of 80-100 degrees to the electrode line (1). Surge arrester according to one of Claims 1 to 4, characterized in that the arc extinguishing chamber (3) appears to be closed for the direct gas outlet of the arc chute (3). • · · · · Surge arrester according to Claims 1 to 5, characterized in that relief holes (101) are provided in the surge arrester housing (10) in the area of the arc chute (3), which are connected to the outside atmosphere via a labyrinth outlet. Surge arrester according to claim 6, characterized in that the surge arrester