DE7819542U1 - OVERVOLTAGE ARRESTER WITH INNER SHORT CIRCUIT FOR OVERLOAD - Google Patents

Description

, SIEMENS AKTIENGESELLSCHAFT Our mark

Berlin and Munich VPA 78 P 1 1 O 8 8RD

Surge arrester with internal short circuit

The invention relates to a surge arrester with
a gas-filled housing, in which electrodes are located in a tubular insulating body at a distance from one another, at least one of which on top of the other | Electrode facing surface is provided \ chen with a MetaHplätt- which produces at Überlastimg the surge inungsableiters a galvanic connection with the opposing electrode i and comparable having a larger diameter than its I with the electrode | has bound surface. I.

^ 5 Such a surge arrester is known I

(DE-PS 21 01 417). By the measure that the very thin r metal plate with a larger diameter than I.

its mounting surface on the electrodes of the lead to be provided, inevitably a different

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06/26/1978

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lent heat conduction of the metal plate to the electrode surface causes. The edge surfaces which do not rest on the electrode therefore melt in the limit load area of the surge arrester on the counter electrode or fuse, if the counter electrode expediently also covered with a metal plate, with this other metal plate. It is thus made possible to give the surge arrester a short-circuit characteristic that is always below the so-called destruction characteristic of the arrester runs.

In addition to this surge arrester with internal short-circuit in the event of overload, surge arresters with external short-circuit mechanisms are also known (DE-PS 19 22 823). In these devices, a soft solder pill is arranged next to an electrode. In addition, a bracket is required which ends shortly before the counter electrode in the operating state. In addition, an _m spring force is necessary. When the arrester I heats up

the soft solder pill melts, the solder is displaced by the ®

Spring force pushed out laterally " ¹ ^ the Bu ¹ ^ sI brings about the external short circuit. It is more economical

the mechanical effort is much lower. In addition, no additional external space is required.

Gas discharge surge arresters are often used, for example, in the main distribution board to protect communication lines used. This creates a high packing density. To the function of such a facility in the long term ensure that Hiufi does not damage insulation

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parts and resilient connections due to overheating can be avoided. Strong heating occurs due to the power loss in the arrester if, for example, an alternating current is fed in _{for a longer period of time, i.e. in the order of about 30 seconds 5 by touching the communication line} Finally, the overvoltage discharges with such low resistance that no more harmful heating occurs.

The object of the invention is to provide a surge arrester with so-called "fail safe" behavior (short-circuit mechanism) to create, in which the heat dissipation from the electrodes is controllable so that on the one hand, the required alternating and surge current loads can be carried out without changing the response behavior and on the other hand the short-circuit mechanism occurs even with long-term low alternating current loads. To solve this problem,

proposed according to the invention that the metal plate

active surface a known layer of a mass of high thermal electron emissivity is applied and anchored in depressions in the surface.

Complete metal electrodes are preferably used, which consist of a material whose Expansion coefficient is adapted to the insulating body material and in which the metal plate by a Undercut of the electrode surface is made.

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It is also particularly economical to use the electrode material Use iron and solder the electrode to a washer made of an alloy or a metal, the expansion coefficient of which in turn corresponds to the expansion coefficient of the tubular Insulator is adapted.

The complete surge arrester consists of a tubular insulating body made of glass or ceramic, which is connected to the electrodes via a glass connection or hard soldering. Compact metal connections on the outside of the electrodes ensure good heat dissipation of the power loss and increase the load capacity of the arrester. With the strength of the undercut or the protruding edge of the pane, the heat dissipation can be controlled in such a way that the required alternating and surge current loads can be carried out without changing the response behavior of the arrester and the short-circuit mechanism also occurs with long-term low alternating current loads. The TTii-py.firt hi ηΚ ] ς (* τηηΐ iiri p> can be positioned with the necessary safety margin below the destruction characteristic

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V arresters are designed to reduce the surge voltage

voltage preferably one or more strips of electrical conductive material, so-called ignition strips. Due to the electrode construction with A metal disc protruding beyond the edge of the electrode {is a low-vapor back space formed so that

the required good insulation of the electrodes from one another even after the surge arrester has been loaded preserved.

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With reference to that shown in the figures of the drawing Exemplary embodiments of the invention will be explained in more detail below with further features. In the ? Figures are corresponding parts with the *

provided with the same reference numerals. It shows:

1 shows a surge arrester according to the invention on average,

Fig. 2 shows a preferred embodiment of a KLek; trode of the surge arrester is section j

and

3 shows a further exemplary embodiment of an electrode in section.

. The surge arrester shown in Figure 1 \ a so-called button type and consists mainly | Chen from two stepped frustoconical electrical § 6 and 7, which are of a tubular in the ends, are used in gas-tight ^h this embodiment, existing ceramic insulator. 4 The gas-tight connection of the insulating body k to the electrodes 6, 7 takes place via a glass connection or a hard solder layer. The compact metal connections 8 and 9, which are soldered to the outer electrode walls in the tapered electrode part, ensure good heat dissipation of the power loss that may occur and thus increase the load-bearing capacity of the gas discharge surge arrester.

The gradation in the electrodes 6, 7 is used for mechanical Guiding of the metal connections 8 and 9, which are made of iron, for example copper-plated iron pins can also be used. The elec-

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Trodes 6, 7 are on their surfaces facing each other each provided with a solid metal disc 1, which has a larger diameter than the area connected to the electrodes 6, 7, so that in the interior of the conductor a rear space 10 which is poor in damping is formed. This low-vapor back space 10 is above all then of particular importance when reducing the surge voltage of the surge arrester one or more strips of electrically conductive a Material, for example made of graphite, so-called Zündv strips 5 applied to the inner wall of the insulating body 4 are. This means that even if there is an offset from the metal disks 1 that may occur Sufficient protection of the rear space 10 of the arrester is guaranteed, so that in the case of a surge arrester with ignition mark 5, there is always a sufficient residual insulation distance between electrodes 6 and 7. the two metal disks 1, which are shown in this exemplary embodiment in the melted together state, have on their active surfaces a waffle 3, in which a layer 2 of high thermal electron emissivity is anchored. Layer 2 be * - / -. stands for example from a mixture of alkali halide, Titanium hydride and barium aluminum alloy powder. Layer 2 is used in particular for reduction the response voltage of the surge arrester. Surge arrester with activation layers known per se are also characterized by a low arc transition, so that with high-current ι Discharges the energy loss in the gas discharge surge arrester remains small.

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The electrode shown in Fig. 2 has the essential

lent advantage that it can be made from a single piece of metal by turning. The solid metal disk 1, for example the electrode 6 with the connecting bolt 8, is produced by turning the active electrode surface backwards. Even the waffle 3 'in which the electrode activation layer 2 is anchored can at the same time be made in the metal piece in the form of concentric grooves during the turning process. The material for the piece of metal must be a solv ^! Ches are chosen that has an expansion coefficient matched to the material of the insulating body. A cobalt-iron-nickel alloy, for example, is suitable.

15th

In the case of the electrode shown in FIG. 3, there is again the connecting bolt 8 and the solid metal disk 1 made of one piece of metal. The metal disk is produced by back-turning the active electrode surface. Also the armament 3, in which the Activation layer 2 is anchored, can be produced at the same time when turning. The difference to that / The electrode shown in Fig. 2 consists in that the electrode part 6 is designed in the form of an annular disk is soldered as a single part to the connecting bolt 8. This embodiment has the advantage that as an electrode material, for example, cheap iron can be used, while only for the electrode part 6 (washer) is a relatively expensive metal alloy with a coefficient of expansion adapted to the insulating material is to be used.

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The invention is based on the illustrated embodiment "examples not restricted. In particular, the invention is also applicable to other forms of surge arrester than with so-called button arresters, for example Can be implemented with two-line arresters.

5 claims,
3 figures.

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VPA 78 P Π Ο 8 BRD summary

Surge arrester with internal short circuit

The invention relates to a surge arrester with a gas-filled housing in which in a tubular insulating body (4) facing electrodes (6, 7) at a distance, of which at least one is on its surface facing the other electrode is provided with a metal plate (1), which in the event of overload of the surge arrester establishes a galvanic connection with the opposite electrode. In the case of the surge arrester, the heat dissipation from the electrodes (6, 7) should be controllable that the alternating and surge current loads can be carried out without changing the response behavior and the short-circuit mechanism smus occurs even with long-term low alternating current loads. The invention sees ^ about this. that the metal plate (1) is designed as a compact disc on its active surface

? q sine ^aT> known layer ^ 2 ^ aiig ginpr mass "hofa *»? thermal electron emissivity is applied and anchored in depressions (3) in the surface. A surge arrester according to the invention is particularly suitable for protecting communication lines (FIG. 1).

Claims (5)

-1- VPA TB P 1 1 O 8 BRD irüche 1. Surge arrester with a gas-filled housing, in which in a tubular insulating body opposite electrodes at a distance, of which at least one is provided with a metal plate on its surface facing the other electrode, which in the event of overload of the surge arrester establishes a galvanic connection with the opposite electrode and that has a larger diameter than his U has surface connected to the electrode, thereby characterized in that the metal plate (1) is designed as a compact disc on which Active surface a known layer (2) from a mass of high thermal electron emissivity is applied and in depressions (3) in the \ 15 surface is anchored. 2. Surge arrester according to claim 1, characterized in that the tubular insulating body (4) is provided with at least one strip of electrically conductive material as an ignition / \ strip (5) which extends over at least part of the inner wall of the insulating body (4) stretched. 3. Surge arrester according to claim 1 or 2, characterized in that the Electrodes (6, 7) are solid cylindrical and the metal plate (1) on the surface by an undercut the electrodes (6, 7) is formed. -2- P 1 1 ο 8 I. 4. Surge arrester according to one of claims 1 I to 3, characterized in that I that the electrodes (6, 7) each with a metallic I see the ring washer soldered to the connection with I 5 the insulating body (4) is attached to its material : has a suitable expansion coefficient. 5. Surge arrester according to claim 1 or 2, characterized in that the 10 frustoconical electrodes (6, 7) the metal connections (S, 9) enclose, lead and are connected to one another by brazing.