DE2437722A1 - Anti-arcing protection for overhead conductor rail - with extending horns with fuse links to isolate arc - Google Patents

Abstract

Special anti-arcing horns are fitted to either side of the insulating section on the overhead electric supply line. The horns have a main shaft which leads upwards into an insulated (5) tube. The shaft is circular in cross section and is split into upper and lower sections inside the insulating tube. The two parts are joined by a piece of fuse wire (7). As the arc climbs upwards between the horns it crosses the fuse wire, which melts after a set time interval. The secondary arc across the burnt out fuse wire heats and expands the air inside the tube and thus helps the internal spring to throw the upper shaft section outwards.

Description

Arcing breaker for blahrleitungsstreckers electrical Railways The invention relates to an arc interrupter for line section disconnectors electric railways.

When driving on section separators, there are potential differences between the two neighboring sections of the conductor line with the pantograph Arcs drawn across the isolating section of the section insulator, which occur with longer Burning time can lead to damage, such as breakage of the insulator or burn-off of the cable or suspension cable. Particularly harmful are arcs that occur when driving into an activated, However, non-earthed contact line section will be pulled because of such an arc in unfavorable weather because of the full recurring voltage burns so long, how the locomotive takes energy.

Arc horns are used as a means of extinguishing arcs known. In these arcing horns, the arcing rises due to thermal lift high, is lengthened, strongly cooled and deionized so that it is under favorable Circumstances goes out.

The disadvantage of this arrangement is that the arc can only be used under favorable conditions Conditions (current strength, potential difference, weather, and Air flow, the latter also through the moving locomotive) comes to an end. also-show Experience from operation and test field that the arc burning freely in the air must reach a great length so that the deletion conditions are met. So is there is a risk that the spatially extensive arc (with lead wire voltages from 15 kV up to 5 m in length) to other pipe parts and cause for further malfunctions in overhead contact line sections not directly involved or for short circuits will.

The invention is based on the task of creating a facility by means of which an arcing occurs with currents occurring during operation, potential differences, Weather and air flow conditions after a short time and with avoidance large arc loops comes to extinction.

This object is achieved according to the invention in that on per se known, directed vertically or obliquely upwards at the two ends of the catenary Arc horns äe an extinguishing tube made of insulating material is attached, the one Contains discharge electrode, which protrudes from the top of the extinguisher tube and the bottom, inside the extinguishing pipe, indirectly or directly by means of a protective wire is connected to the arcing horn, one between the two catenary ends generated arc due to its thermal and electromagnetic Properties on the arc horns to the top of the ejection electrode rises, whereupon after a short time the fuse wire melts and in its place a secondary arc is created, the thermal effect of which causes the air to move in the surrounding chamber expands suddenly and the ejection electrode out of the extinguisher tube flung out.

A short time after this interruption in the line path, the Electric arc.

Particularly good effects in terms of guiding and extinguishing the arc arise when this arc interrupter has other herbal features according to the invention has - with which a rapid ejection after the melting of the fuse wire the ejection electrode is effected, for example, by the extinguishing tube wholly or partly consists of an insulating material, which when the fuse wire melts and / or - under the thermal effect of the secondary arc, vapors - and / or gaseous Releases decomposition products, and / or by the chamber surrounding the fuse wire is completely or partially filled with a substance that melts when the fuse wire and / or vapors and / or gaseous under the thermal effect of the secondary arc Releases decomposition products, and / or by placing the ejection electrode under the voltage one li'edér-stands; - with which the trespassing of the ascending Arc from the arc horn (below the extinguisher tube) to the upper end of the Ejection electrode is favored, for example, by placing the arc horn underneath branch one or more auxiliary electrodes upwards from the extinguishing pipe, and / or, by placing one or more auxiliary electrodes outside of the upper end of the ejection electrode of the extinguisher pipe pointing downwards.

Is favorable as protection against weather influences and as a guide of the arc when the end of the ejection electrode protruding from the top of the extinguishing tube is designed as a cap that is slipped over the upper end of the extinguishing pipe, especially if the inside of the cap is completely or partially lined with insulating material is.

In general, it is useful to measure the cross-section of the extinguishing pipe To make a circular ring, but in different cases of use, a different one To choose cross-sectional shape.

Usually the air is caused by the heat of the rising The arc has been strongly ionized and has thus become conductive until it is ejected the ejection electrode as far from the distance between the conductive parts below the extinguisher tube and the upper end of the ejection electrode aborted that the arc after throwing the ejector electrode no longer on the senior Parts below the extinguishing pipe can spring back. When the air flow is very weak in connection with unfavorable weather conditions, however, there is - albeit only slight - possibility that the arc will spring back again. To jump back Preventing the arc or at least making it very difficult is another Implementation of the inventive concept provided that the lower and / or upper auxiliary electrodes so with the fuse wire or an auxiliary schinelzdraht directly or indirectly are connected that they after the melting of the fuse wire or the HilSsschmelzdrahtes fold down or up. In another embodiment it is thought that the outer distance between the arc horn below the extinguisher tube and the upper end of the ejection electrode wholly or partially bridged with conductive materials is that initially the ascent of the arc to the'oberen end of the ejection electrode favor, but during the sufstieg as a result of the thermal effect of the arc melt, evaporate and / or decompose, causing the arc to bounce back on conductive parts below the extinguishing tube after the ejection electrode has been ejected prevented or at least valued.

In general, it will be useful if the fuse wire is made of Made of metal. However, it is possible to use a conductive non-metallic instead Fabric or a Combination of metallic and non-metallic To use substances.

It is sometimes useful to wholly or partly from materials that are exposed to the noise of the secondary arc melt, evaporate and / or decompose. Hit them can avoid the danger or at least greatly reduced that of the ejected ejection electrode goes out.

For the escape of the vapors or the gaseous decomposition products to the top are one or more channels in the longitudinal direction of the ejection electrode to be provided.

Exemplary embodiments of the invention are explained with the aid of the drawing. FIG. 1 shows a contact line section separator with arc interrupters according to the invention; she i g. 2 shows a section through an arc interrupter according to the invention a fixed auxiliary electrode on the arc horn; F i g 3 a section through a Arc interrupter according to the invention with a hinged auxiliary electrode on Arc horn and a fixed auxiliary electrode at the top of the ejection electrode.

The two catenary ends 1 (Fig 1) are in a known manner electrically separated from one another by an insulating piece 2. Hit the metallic runner 3 are the ends of the contact line, the insulating piece and the arc horns known per se 4 mechanically connected to each other. The arc horns are according to the invention Arc interrupter 21 with its auxiliary electrodes 6 placed on it.

The arc interrupter in FIG. 2 consists of an extinguishing tube 5 Made of insulating material, in which they are connected to one another via a fusible link 7 Exchange electrode 19 and ejection electrode 8 are located. The extinguisher pipe is over the metallic socket 9 connected to the arc horn 4 and fastened with screws 10. The auxiliary electrode 6 branches off from the arc horn upwards. The top is at the ejection electrode the metallic cap 12 is put on, which is provided with an erosion syringe 14 and is lined with insulating material 13 on the inside. With the compression spring 11 is the cap and thus the ejection electrode is also pretensioned with respect to the extinguishing tube. Below of the extinguishing pipe, up to the branch of the auxiliary electrode, is the arcing horn isolated by means of insulating tube 20.

The arc interrupter uses the property of the arc, that it is under the influence of thermal buoyancy and the magnetic field accompanying the current to the highest point of an electrode arrangement at potential migrates upwards and at the same time, due to the strong ionization of the air, also greater striking distances can skip.

am, for example, from the pantograph of a locomotive via the insulating piece Drawn arc moves over the spread arcing horns and the auxiliary electrodes up and jumps - depending on conditions such as air currents, etc. - on an or both sides of the section insulator on cap 12 over. The auxiliary electrodes are on the side and arranged opposite to the extinguishing tubes and ensure that the arc skips onto at least one of the caps regardless of the wind direction. The skipping is favored by the large conductive surface of the caps.

From the moment you jump onto the cap, the current flows exclusively through the fuse wire and the ejection electrode inside the extinguishing tube - the fuse wire melts due to the flow of current according to its melting characteristic after a certain selectable time as a function of the current. The current flow is through a Maintain the secondary arc, which forms immediately in place of the fuse wire. In the process, a strong overpressure suddenly forms in the chamber 15 strong heating of the air in the chamber and the release of gas from the very hot inner wall of the extinguishing pipe. This overpressure flings In cooperation with the compression spring, the discharge electrode out of the extinguisher tube. The secondary arc drawn in the extinguishing tube is deionized by a strong release of gas and extinguished, which also extinguishes the external arc.

Because of the missing cap, it can be clearly seen from the outside that the Arc interrupter has responded. He can then easily by means of the screws 10 be replaced. The protective effect of the arcing horns also remains obtained with the ejection electrode ejected.

Due to different characteristics of the two fusible links, it becomes achieves that only one arc interrupter responds at first and at a later one The second is the case, but only after a long arc downtime.

In the case of the arc interrupter in FIG. 3, the arc jump to the itu joint electrode 8 'through only a small distance between the auxiliary electrode 6 of the arc horn 4 and the auxiliary electrode 16 of the discharge electrode favors. With such a small distance between these two auxiliary electrodes However, there is a certain probability that the arc after Ejecting the ejection electrode jumps back onto the auxiliary electrode 6 and there only goes out after a long period of use or does not go out at all. This danger is prevented by the auxiliary electrode, 6 in front of the Ejection of the ejection electrode folds down and thus increases the spark gap. After skipping the When the arc hits the ejection electrode, the current flows in parallel through the fuse wire 7 and the auxiliary fusible wire 17, which are designed so that first the auxiliary fusible wire melts. The auxiliary electrode 6 folds with the auxiliary fusible wire after it has melted to which the film electrode 6 was connected via the non-conductive connector 18, as a result gravity down. Only then does the fuse wire melt through, whereupon In the manner described above, the ejection electrode is thrown out of the extinguishing tube 5 will.

Sometimes it will be useful if the two arc interrupters of a section separator are designed differently from one another, or on a section separator only use an arc interrupter and the other end of the contact line in to end a simple arc horn.

Claims (15)

Claims Arc interrupter for electrical contact line section disconnectors Railways, characterized in that on per se known, at the two ends of the catenary Arc horns (4) pointing vertically or diagonally upwards each have an extinguishing pipe (5) is made of insulating material, which contains an ejection electrode (8) -, which protrudes from the top of the extinguishing pipe and the one below, inside the extinguishing pipe, by means of a fusible wire (7) directly or indirectly with the arc horn is connected, with one coming about between the two ends of the catenary Arc due to its thermal and electromagnetic properties rises up the arc horns to the top of the ejection electrode, whereupon after a short time the fuse wire melts and in its place a secondary arc arises, due to the thermal effect of which the air in chamber (15) expands suddenly and ejects the ejection electrode from the extinguisher tube. 2. Arc interrupter according to claim 1, characterized in that that the extinguishing pipe consists entirely or partially of an insulating material that is used in Melting of the fuse wire and / or under the heat effect of the Secondary arc Gives off vapors and / or gaseous decomposition products and thus the ejection causes or supports the ejection electrode. 3. Arc interrupter according to claim 1 or 2, characterized in that that the chamber (15) is completely or partially filled with a substance that melts of the fuse wire and / or vapors under the thermal effect of the secondary arc and / or releases gaseous decomposition products and thus the ejection of the contact electrode causes or supports. 4. Arc interrupter according to one of the preceding claims, characterized in that the ejection electrode is under the tension of a spring (11) indicates that the ejection electrode is ejected after the fuse wire has melted causes or supports. 5. arc interrupter according to one of the preceding iVa claims, characterized in that 'from the arc horn below the extinguishing pipe (5) one or several auxiliary electrodes (6) branch upwards, which skip the ascending Favor the electric arc on the upper end of the bump electrode. 6. Arc interrupter according to one of the preceding claims, characterized in that from the upper end the ejection electrode one or more auxiliary electrodes (16) outside of the extinguishing pipe point downwards, the jumping of the ascending arc from the arcing horn to the upper one Favor end of the ejection electrode. 7. Arc interrupter according to one of the preceding claims, characterized in that the end of the ejection electrode protruding from the extinguishing tube at the top is designed as a cap (12) which is slipped over the upper end of the extinguishing pipe is. 8. Arc interrupter according to claim 7, characterized in that that the inside of the cap (12) is completely or partially lined with insulating material (13) -is. 9. Arc interrupter according to one of the preceding claims, characterized in that the extinguishing pipe (5) has an annular cross-section or one. other cross-section appropriate for the application in question having. 10. Arc interrupter according to at least one of claims 5 or 6, characterized in that the auxiliary electrodes (6) and / or (16) so with the fusible wire (7) or an auxiliary fusible wire (17) directly or indirectly are connected that they are after the melting of the fuse wire or the, auxiliary fuse wire downward or fold upwards and thus the Arc on conductive parts below the extinguishing pipe after being ejected avoid the ejection electrode or at least make it more difficult. 11. Arc interrupter according to one of the preceding claims, characterized in that the outer path between the arc horn is below of the extinguishing tube and the upper end of the ejection electrode in whole or in part is bridged by conductive materials, which initially cause the arc to rise to the top of the ejector electrode, but during the ascent melt, evaporate and / or decompose as a result of the thermal effects of the arc, This causes the arc to jump back onto conductive parts underneath the extinguishing tube prevented or at least made more difficult after the ejection electrode has been ejected will. 12. Arc interrupter according to one of the preceding claims, characterized in that the fusible wire is made of metal or a non-metallic Substance or a combination of metallic and non-metallic substances consists. 13. Arc interrupter according to one of the preceding claims, characterized in that the ejection electrode is wholly or partially made of materials consists, -which melt under the thermal effect of the secondary arc, evaporate and / or decompose. 14. Arc interrupter according to one of the preceding claims, characterized in that only on one side of the section separator the parts of the Arc interrupter features according to any one of the preceding claims and that on the other side of the section separator the contact line in a simple one Arc horn ends. 15. Arc interrupter according to two of claims 1 to 13, characterized characterized in that the parts of the arc interrupter are on each side of the section insulator Have features of different claims. L e r s e i t e