DE838916C - Fire chamber switch with tubular switch pin - Google Patents

Description

Extinguishing chamber switch with a tubular switching pin Extinguishing chamber switches have become known in which the chamber pressure that arises when switching off and acts on the switching pin in the switching off direction is also transmitted to the opposite end of the switching pin, where it mainly aims in the same way towards the end of the switching off movement that the first Part of the switch-off movement is absorbed bumplessly by the switching pin accelerated by the chamber pressure on the last part of the switch-off movement. This type of counteracting the chamber pressure, which accelerates the moving contact element during the disconnection process, is known for both air and gas and liquid switches. A similar pressure relief of the moving contact piece when switching on is not necessary with these switches because the short and quickly extinguishing switch-on arc # in the case of liquid-free switches due to the lack of vapor development and in the case of liquid switches due to the only partial filling of the chambers with liquid, no appreciable switch-on overpressure arises. But if you want to build C-switches with a very short switch-off time, the arcing chambers must be completely filled with 01 and must not contain an air cushion, because this delays the formation of the chamber pressure required for the necessary flow of extinguishing agent and the arc that would otherwise occur at the first current zero passage after its Initiation could be interrupted, extended. On the other hand, if the arcing chambers are completely filled with 01 , difficulties arise when switching on on a short circuit, because the switch-on arc creates a very high pressure surge in the chamber which, even on the short rollover path, is capable of strongly pushing the switch pin into the arcing chamber to slow down and prevent quick and safe contact. The result is welding of the contacts and failure of the switch.

In order to avoid this, according to the invention, similar to the known manner when switching off, the switching pin is now also relieved of the chamber pressure when switching on, but for which the known, more or less elastic transmission means are no longer sufficient due to the instantaneous pressure equalization required. In the new switch with a short switch-off time, the hollow switch pin and the arcing chamber are completely below 01 and do not contain any air spaces. The very high chamber pressure that arises when switching to a short circuit is instantaneously transferred to the opposite end of the switching pin and its support surface by means of the practically incompressible extinguishing liquid through the hollow pin, and the switching pin is thus relieved of the chamber pressure. Two designs can be used for the hollow switch pin. The tubular switching pin can have the same diameter over its entire length. It must then move with its end opposite the arcing chamber within a fixed guide sleeve. However, the switch pin can also have different diameters along its length, the outer diameter of the switch pin part that protrudes into the chamber corresponds to the inner diameter of the remaining tube part with which the switch pin slides over a stationary guide piston. It therefore forms either the hollow switching pin, the jacket or the piston of the device regulating the switching speed.

Arrangements have already become known in which a hollow Switching pin is used, in which there is a fixed pump piston. This arrangement should also generate a jet of liquid during the shutdown process be injected into the arc path. Such an arrangement is of course not suitable to detach the switch pin from the one in the arcing chamber when it is switched on to relieve any excessive nicks.

On the basis of the illustration, which represents one of the possible embodiments, the invention is explained in more detail.

The illustration leaves the center piece of a columnar, low-oil high-voltage switch recognize. The switch housing i is made of insulating material; it's in the middle piece 2 of the switch assembly attached and supports a frame 3 above, above which a Closing hood 4 is located. An extinguishing chamber is built into the interior of the switch housing, which consists of the metal housing 5 and the bottom 6 made of insulating material. The quenching chamber is attached to the frame 3 by means of the support 7 provided with spokes. At Instead of the simple quenching chamber shown, a so-called flow quenching chamber can also be used find use with a differential pumping piston; the drawn tulip contact 15 can also be replaced by a pushbutton contact in order to shorten the switch-off time will. The hollow switching pin 8 is with the forked drive lever 9 through the Driving pin io, which engages in the link i i located on 'the switching pin, necessarily coupled. The hollow switch pin 8, the one below, the sliding contact 12 carries, slides on a provided with a piston 13 guide rod 14. The tubular Switching pin 8 is in its upper part, as far as it is in the switched-on state the arcing chamber engages, tapers to a diameter equal to the inner one Diameter of the lower part of the switch pin is. Instead of the tapered pin a switch pin of constant diameter can also be used, which then but does not reach over a plunger, but when switched off in a sleeve pushes. The arcing chamber carries the stationary switch contact 15 inside, the is protected by a hood 16.

If now when closing the switch contacts an overpressure in the Arcing chamber occurs, it acts on the upper ring surface of the switching pin and tries to push the switch pin out of the chamber. The arcing chamber pressure but is planted through the bore 17 in the tapered pin part also in the larger one Bore 18 of the lower pin part to the stationary piston 13 of the guide rod 14 continued. The pressure in the hollow pin is the same as in the quenching chamber. Since the diameter of the bore 18 is equal to the outer diameter of the tapered Is the switching pin part, so is the annular pressure surface in the bore 18 equal to the upper ring surface of the switch pin part protruding into the arcing chamber, and the downward and upward forces acting on the switch pin are lifted each other up. The new arrangement does not only affect the switch-on movement under short circuit, as described, favorably, but in the same and in itself As is known, it also affects the switch-off movement, which results in very short switch-off arcs and switch-off times are enabled.

Claims (1)

CLAIMS: i. Extinguishing chamber switch with tubular switch pin with arcing chamber under 01 and completely filled with 01 , characterized in that the chamber overpressure generated by the starting arc and acting on the switch pin tip is rigid with the help of the extinguishing fluid through the hollow pin, avoiding elastic intermediate links and using a fixed support surface an oppositely located, equally large switch pin surface is transferred and so its effect on the switch pin movement is canceled, z. Extinguishing chamber switch according to Claim i, characterized in that the length of the switch pin protrudes into the chamber when it is switched on is tapered to a diameter which corresponds to the inside diameter of the remaining part of the switch pin. 3. arcing chamber switch according to claim i, characterized in that the tubular switching pin has the same diameter over its entire length and moves with its end opposite the arcing chamber within a fixed guide sleeve closed at the end. Referenced publications: German patent specification No. 648477.