DE1159538B - Fire chamber for electrical switching devices - Google Patents

Description

Arcing Chamber for Electrical Switching Devices The invention relates to an arcing chamber for switch-disconnectors with arc extinguishing by gases flowing through the arc can be split off from the walls of the extinguishing chamber.

The switch disconnectors can switch all operating currents on and off; she can also switch on short-circuit currents; but they cannot short-circuit currents switch off.

In the course of development, two main groups emerged for the extinguishing chamber, namely 1. the narrow-gap extinguishing chamber, 2. the tubular extinguishing chamber. The narrow gap chambers consist of two parallel walls, between which a fixed contact for the auxiliary knife is arranged, and an auxiliary knife which only opens after the main knife has been opened and therefore the switching arc between the parallel walls burns between the fixed contact and the auxiliary knife. The parallel walls are made of materials that, under the influence of the arc, split off gases that extinguish the arc. The magnetic field distribution causes the arc to move. This creates a gas pressure difference behind and in front of the arc, which acts approximately in the same direction as the arc's own magnetic field. The gas flow will act in the respective direction of the radius of curvature of the arc path. The entire arc is blown across each track element, mainly with the amount of gas that each track element generates. This creates dead spaces in the open or almost open narrow gap chamber in which soot accumulates, so that the chamber becomes inoperable over time.

Due to the field effect, the gas flow and disturbances caused by foot point migrations, Air currents and pollution are caused, the arc will always be more curved and takes on a torrent-like shape. Come different parts of the Arc too close to each other, a breakdown occurs and the path of the arc occurs is shortened, which means an extension of the deletion time. At the same time migrates the arc deeper and deeper into the narrow gap. To its safe deletion To achieve, the active plate area must be large, whereby the overall length and the The overall height of the switch becomes large, which is especially true in clad or encapsulated Switchgear makes the installation of such switch disconnectors difficult or impossible. A Another disadvantage of the open or almost open narrow gap chambers is caused by that the wide gas outlet ionized gases often flash over at neighboring live parts leads.

In order to reduce the wide gas outlet, the one facing away from the pivot point Side of the narrow gap chamber is also closed with gas-emitting substances. By however, this measure is superimposed on the direction of migration caused by the magnetic field of the arc, namely away from the fulcrum of the switch, through which now on Closure part of the chamber resulting in stronger gas release and the effect of the closure even a gas flow tendency that works in the opposite direction. This increases the risk that the arc migrates along the auxiliary knife to the pivot point.

Attempts have been made to eliminate this disadvantage by going through additional blow coils or unwound fittings made of magnetic material has strengthened the self-generated magnetic field. Both the elaborate blow coils and unwound fittings made of magnetic materials do not prevent themselves create dead spaces in the part of the extinguishing chamber facing the pivot point, in which especially soot is deposited, which is so compacted by the movement of the auxiliary knife the arc will take different paths than expected by the design is. This disadvantage could only be overcome through increased maintenance and frequent chamber changes come first, but this greatly reduces the incentive to use the switch disconnector. Around the flat chamber plates of moisture and the charring effect are less current To make arcing independent, it has been suggested that the chamber be made of thermoplastic Manufacture plastics, care had to be taken that the slot-shaped Gap in which the switch blade is located after leaving the fixed contact moves a certain distance, remains open on at least two sides so that none initial pressure increase in the slot-shaped space is possible. Through the Completion of the narrow gap chamber on the side facing away from the knife pivot point The gas flow has been given a new direction, that of the natural field effect on the arc is roughly opposite.

In the case of small to medium currents, this increases the speed of movement of the arc too small, which leads to stronger erosion fields in certain zones and in the case of strong currents, this leads to arc migrations in the direction of the knife pivot point gives.

In order to overcome this disadvantage, it has been proposed to reduce the space between Knife bow and closure to enlarge and also the closure with gas outlet openings' to provide.

Also load, or. Power isolators have been developed that move the auxiliary knife completely into the narrow gap chamber and achieve the function of the auxiliary knife through special actuation and locking mechanisms. The disadvantages of such load or power disconnectors are: 1. The mechanical system for the auxiliary knife and the locking device is too complex.

2. The mechanics have to be maintained at an increased level, because during operation unavoidable sooting and soiling, functional errors can occur, z. B. when switching on over soot deposits, moisture and other dirt Between the lock and the auxiliary knife a light gap can occur, although it is from the Main knife is short-circuited immediately. Or, it becomes the auxiliary knife when it is switched off or the locking mechanism blocked, so that the interruption of the arc does not take place in the narrow gap chamber, but outside the extinguishing chamber, especially this is because both the movement of the auxiliary knife and that of the locking lever does not necessarily depend on the movement of the main knife, but on pretensioned ones Feathers.

The tubular extinguishing chambers are constructed in such a way that the contact of the auxiliary knife and the hook-shaped angled end of the auxiliary knife is surrounded by gas-releasing walls so that the extinguishing chamber is closed by the auxiliary knife end. The gases produced when the arc is drawn up cannot escape from the chamber; they cannot extinguish the arc within the chamber either, because no significant gas flow or cooling can take place. The arc can only be extinguished by the flow of the expanding gases and the associated cooling after the end of the auxiliary knife has emerged. These quenching chambers have several disadvantages, namely: 1. With small currents, the gas generation is small, so that the quenching of the arc is difficult or not achieved at all. 2. The active gas-emitting area is small, so the service life of the extinguishing chamber is short.

3. Parts of the arc with highly heated gases shoot out of the chamber like jets as a result of the high pressure and thus require large safety distances.

4. The time between the contact opening and the exit of the auxiliary knife from the chamber, especially in the event of nine or unforeseen events, because of the high pressure increase overflow be short. This makes a special quick mechanism for the auxiliary knife necessary. This must be set up in such a way that when it is switched to a short circuit the auxiliary knife lags behind the main knife, as this extinguishing comb is switched on Cannot bear short circuit because of the very high pressure increase. Also bring Such quick mechanisms for the auxiliary knife are further sources of error in the switch and increase the price considerably.

In order to eliminate the disadvantages mentioned under points 1 and 2, movable elements have been built into the closed tubular chamber, which narrow the arc path after the escape knife or switch pin emerges. The sooting of the sliding surfaces and sliding joints leads to the fact that the movable elements in the chamber are blocked over time without this being recognized beforehand and the switch cannot extinguish the arc.

Mat has also built tubular arcing chambers in which the fixed contact for the auxiliary knife or the switching pin is movably arranged so that the auxiliary knife pulls it along a predetermined distance and a spring is tensioned in the process. After reaching a stop, the contact breaks loose from the auxiliary knife or switch pin and is pulled back by the tensioned spring and the gas pressure, which acts in the same direction. At the same time, chamber wall parts are pressed against each other by spring force, so that the arc path is narrowed and the switch achieves arc extinction even with small currents. The complex mechanics of the contact is also subject to sooting, and the deficiencies described in points 2, 3 and 4 remain.

In order to improve the extinguishing effect, especially with larger currents or overflows, the exit path within the chamber for the gases is designed in a narrow gap chamber so that, according to the invention, the parallel walls of the extinguishing chamber have the shape of an outwardly widening nozzle, with the fulcrum of the auxiliary blade facing delimitation of the chamber - inner delimitation - runs parallel to the trajectory of the auxiliary blade and forms a sealing gap. The outer delimitation of the chamber is shaped in such a way that, with the inner delimitation, it results in an outwardly widening nozzle. The arc burning between the contact and the I-Elfs knife generates a strong gas emission on the side walls. The gases can only exit along the nozzle. The gases entrain the arc so that the arc path is lengthened. This increases the arc resistance as if the 1-Elf knife had been pulled out of the quenching chamber more quickly. The gas flow sweeps across parts of the arc path, so that the deionizing effect of the gas flow is considerably increased, since highly ionized plasma parts are displaced by unionized or slightly ionized gases. Furthermore, the wear and tear of the chamber material is distributed more over the surface of the inner wall of the nozzle, so that more chamber material is available for extinguishing, which ultimately increases the service life of the extinguishing chamber.

In the quenching chamber according to the invention act on the part of the arc which transversely to the nozzle path] places all of the gas produced. The blowing of these parts is significantly more energetic, so that the arc occurs at the same time in the nozzle chamber is experiencing a greater expansion. Due to the gas flow inside the nozzle, the Increased ventilation, the arc extinguished earlier and the entire arc extinguishing necessary expansion of the arc is reduced.

This ensures that the nozzle extinguishing chambers are kept small can. Since the exiting gases are largely relaxed in the nozzle, your The temperature is greatly reduced and its degree of ionization is considerably reduced, and only short tufts of expansion emerge from the narrow gap nozzle chamber. A special The advantage of this chamber is that because of the directed flow in the narrow gap nozzle chamber there are no dead spots in the extinguishing room. When switching small currents frequently fairly even soot deposits can occur from the chamber, such as the experiments show to be eliminated in such a way that the deletion time increases, so that a strong gas formation occurs and blows out the soot. It kind of arises Self-cleaning a.

Another, quite significant advantage of the nozzle-shaped discharge opening the chamber is that the auxiliary knife can be firmly connected to the main finesser, care must be taken that the metallic connection of the auxiliary knife with its mating contact is only interrupted after the main knife has been opened.

If the auxiliary knife and the contact for the auxiliary knife are appropriately designed, the auxiliary knife leading the main knife can be switched to short circuit (initially about 20 kA) without damage to the narrow gap nozzle chamber or the auxiliary knife. However, this makes it possible to dispense with a special mechanism for the auxiliary knife or the contact of the auxiliary knife. This arcing chamber can also be used to switch on and off capacitor banks (up to about 1 WAr at 10 kV).

The construction of the narrow gap nozzle chamber is simple and therefore cheap and particularly suitable for mass production. The invention will be explained in more detail using an exemplary embodiment: In Fig. 1 , the extinguishing chamber 1 is drawn parallel to the two walls 4 and in Fig. 2, a cross section AB of Fig. 1 is shown.

The narrow gap chamber 1 consists of the two parallel or approximately parallel walls 4 and is narrowed with the inner delimitation 2 and the outer delimitation 3. In the bottom of the arcing chamber 1 , the contact 5 is inserted. The Hüfsmesser 6 forms with the inner knife edge 7 and the inner delimitation of the chamber 2 a sealing gap. Step out of Hilfsinessers 6 from the contact 5, an arc path formed 9. The induced by the arc track 9 the gas flow drives the arc from its initial position 9 in the position 10. In this case, the arc passes over the between the web 9 and the web 10 causes facing surface and these for gas delivery. This increases the gas flow exiting over a large area and, depending on the magnitude of the arc power, drives the arc in the direction of the drawn arc path 11. As shown, foot point migrations can occur along the outer edge of the auxiliary knife.

Since the gas output increases with the power in the arc, the expansion of the arc with larger currents depending on the current, so that load switch with arcing chamber According to the invention, also larger overshoots (2 to 2.5 times the nominal currents,) can switch successfully.

Claims (1)

Claim: arcing chamber for switch-disconnectors with arc quenching by gases which are generated by the arc from the walls of a chamber which is closed on all sides except for the insertion opening for the moving contact and which contains the fixed contact and which tightly encloses the movement lever of the moving contact, characterized in that the Walls of the chamber on the side facing away from the pivot point of the movable contact is widened in the shape of a nozzle in the direction of the current-separating contact movement. Documents considered: German Patent No. 644 580; German regulations No. 1 046 726, 1053 615, 1 055 084, 1063 248.