DE1615932B1 - Encapsulated arc extinguishing device for switch disconnectors, especially for use in outdoor equipment - Google Patents

Description

The invention relates to an encapsulated arc extinguishing device for switch disconnectors, in particular for use in outdoor devices, consisting of from a tubular chamber with gas-emitting under the action of the arc heat Parts and a separate snap-action switch mechanism housed in the switch head for and off circuit, which is designed so that a contact is made when switching on first, takes place on the main power lines.

The well-known I-reiluft switch-disconnectors consist of a combination of a disconnector with a built-in arc extinguishing device as a load switching point. Essentially, they differ in the d8s switching mechanism, but also in the different arrangement of the load switching point. The arc extinguishing devices of the type on which the invention is based use a snap-action switching mechanism consisting of a spring-loaded toggle lever mechanism for the switching operations. It is always a particular disadvantage that the movable contact, i. H. the switching pin, has a low initial speed and only reaches a high final speed towards the end of the switching process. In addition, the cut-out point cannot be precisely determined, since it is strongly influenced by friction in certain designs. The drive lever remains in the switch-off position so that the isolating distance of the switch is reduced. When it is switched on, the arc extinguishing device is actuated by the swinging disconnecting knife, which is why the load switching point is first loaded before the main contacts of the disconnector interlock, which not only results in an undesirable load on the arc extinguishing device, but also in the event of a short circuit it means destruction of the switch (German design guide 1 249 378).

To avoid these burdens, different ways are regarding the execution of the d6s disconnector has been used, but all of them are susceptible to weathering are.

Furthermore, a load disconnector has become known (German patent specification 1167 936), in which a delayed action of the snap-action switching mechanism ensures that the switching contacts of the arc extinguishing device do not close until the main current paths have been touched. However, this does not take into account that a soot deposit forms on the surfaces of gas-emitting materials, which are usually organic plastics, when they are switched frequently. This can be used to ignite the short-circuit arc even when the switching path is open, and destruction of the extinguishing device is to be expected with certainty.

The invention is therefore based on the object of making the extinguishing process independent of the speed of the drive of the switch and of avoiding with certainty that flashovers occur in the arc extinguishing device when the main current supply is switched on .

The invention consists in that the switching mechanism consists of a spring-loaded switch mechanism, known per se, consisting of a rocker arm system and a toggle spring, for actuating an actuating rod, as well as for tensioning emier mi in a known manner between the latter and a switching tube, which can be triggered as a function of travel by the switch spring for the spring mechanism independent quick disconnection of the load switch point exists and that an additional return spring linked to the drive crank is provided for the immediate restart of the load switch point.

Advantageous further developments of the invention are set out in the subclaims refer to.

The particular advantage that the invention has over the known arc extinguishing devices. offers, lies in the winding of the return spring. If this is not available, the mechanism of the extinguishing device and the actuating lever coupled to it remain in the end position after the switch-off process. When switching on again, the main circuit meets the lever and uses it to return the extinguishing device to the switch-on position. Due to the action of the snap-action switch mechanism, this is achieved before the contacts of the main current path are closed. This is harmless if no current or at most the nine current of the switch-disconnector comes to flow. However, if the device is switched on in response to an existing short circuit, then currents of 25 to 50 times the nominal current can be introduced. This inevitably destroys the extinguishing device and the switch becomes inoperable. In contrast, the return spring causes the switching mechanism and the actuating lever to automatically return to the starting position after the disconnection process; In this way, the contact is made when switching on first on the main current paths, and the quenching device is not involved at all in the switching on process. - A speed profile of the movable contact is achieved according to the invention, which is desired by the electrical task of a perfect arc extinction even in the most difficult network conditions while avoiding reignition. A high initial speed of the movable contact and a low final speed are achieved - and therefore a speed profile which is opposite to the speed profile of known devices. The operating speed has no influence on the switching speed of the movable Xcontact. In addition, the switching point is precisely defined by the lock.

For a better understanding , the invention is shown schematically in the drawing using an exemplary embodiment and explained in the following description. It shows-F i g. 1 shows an overall view of the arc extinguishing device, FIG. 2 shows a longitudinal section through the device of FIG. 1 in the on position, FIG. 3 shows a longitudinal section similar to FIG. 2, but in the SPqnns-tel-lu-n'- 'F i g. 4 shows a longitudinal section according to FIG. 3, but in the switch-off position and F i g. 5 the W6g-time diagram of the moving contact.

The arc extinguishing device consists of a closed unit, which can be attached to each isolating switch, of a hollow insulator 1 which is fastened to a connecting flange 2, the metallic mechanism housing 3 arranged on it and a condensate pot 4 at the lower end. In the bore of the connecting flange 2, an annular, fixed contact 5 is provided. In the cavity of the insulator 1, between the connecting flange 2 and a fastening flange 6 of the housing 3, then attached to the fixed contact 5 is a tubular chamber 7 made of a material that emits gas under the action of the heat of the arc. The movable contact 8 of the device, which is fastened to a metallic switching tube 9 and carries a follow-up pin 10 on the side facing away from it, moves in this tubular chamber 7. At the bottom of the switching tube 9 , a rubber damper 11 is arranged, which dampens the stop of an actuating rod 12. The actuating rod 12 slides in the switching tube 9 and is articulated with its end protruding from the latter with a rocker arm system. The actuating rod 12 is under the action of a compression spring 13 which is supported on its annular shoulder 14 and a collar 15 of the switching tube 9. An annular cam 16 attached to the actuating rod 12 interacts with a spring-loaded locking blade 17 for the switching tube 9 . In the housing 3 a rocker arm system consisting of three levers 18, 19, 20 is provided as a snap-action switch mechanism, the actuating rod 12 is hinged to the lever 19 of the rocker arm and which is under the action of a tension spring as a toggle spring 21. The movement of the rocker arm system in one direction and the other is limited by a stop 22 against which an angle lever 20 comes to rest. A drive crank 23 tensions the rocker arm system in one sense or the other with the aid of drivers 24 and 25. A return spring 26 is suspended between the drive crank 23 and the housing 3 , the effect of which on the drive crank 23 is limited by a stop 27. The shaft 28, which is firmly connected to the crank 23 , protrudes from the housing 3 and carries an actuating lever 29 on the stub shaft, which works together with the disconnector.

The function of the arc extinguishing device when switching off the switch-disconnector is as follows. During the switch-off movement of the circuit breaker, the operating lever 29 of the device is swiveled out and thereby the crank 23 is moved in a clockwise direction, so that the toggle lever system 18, 19, 20 is moved out of position F i g. 2 by the driver 24 in its dead center position F i g. 3 is brought. The toggle spring 21 is tensioned, the return spring 26 is pretensioned and the switch-off spring 13 is tensioned by entrainment of the actuating rod 12. At this moment, the pawl 17 is pushed aside by the cam 16 of the actuating rod and thereby the lock of the switching tube 9 is canceled, which under the action of the opening spring 13 in the position of FIG. 4 cuts. The movable contact 8 is moved away from the fixed contact 5 in quick disconnection, the arc in the raw chamber is extinguished and the current is interrupted. The switching tube 9 strikes with its damper 11 on the head 14 of the actuating rod 12, so that due to its kinetic energy, the rocker arm system out of the dead center position and under Wirlm: ag of the toggle spring 21 in the off position F i g. 4 is brought. The movement of the rocker arm system from the dead center position to the switch-off position has no effect on the movement of the crank 23, since there is a sufficiently large distance between the two drivers 24 and 25. The crank 23 is turned a little further and the return spring 26 is fully tensioned until the actuating lever 29 is released from the circuit breaker. Under the action of the return spring 26 , the actuating lever 29 now swivels back into its starting position of the switched-on load switching point, the crank 23 being rotated back as far as the stop 27 . The driver 25 takes the rocker arm system 18, 19, 20 with it in a backward movement to over the dead center position, so that it moves into the starting position F i g under the action of the re-tensioned toggle spring 21. 2 is brought. The operating rod 12 is pushed back into the tube chamber by the rocker arm system and thus also the switching tube 9 until the switch-on position of the device is restored by the contact of the contact pieces 5 and 8. The arc extinguishing device is ready for the next switch-off process. Because the operating lever 29 has been pivoted back, the isolating distance of the open load break switch is not reduced by the presence of the load switching point, and the latter is also not involved in the closing process.

The main current path is only electrically parallel to the quenching device as long as it touches the contacts of the isolator. After that, the main current path is only connected to the extinguishing device (via the actuating lever 29) when it is switched off, so that there is a series connection. The arc is now extinguished, and then the operating lever is stripped from the main circuit and returns to its starting position. The main current paths and thus the switch remain open.

When switching on, the main current path is contacted first with the isolating contact and only then touches the operating lever of the extinguishing device.

In Fig. 5 shows curve a the speed profile of the movable contact piece of a switch according to the application, while curve b corresponds to the respective known devices.

Claims (2)

Claims: 1. Encapsulated arc extinguishing device, for switch disconnectors, in particular for use in outdoor devices, consisting of a tubular chamber with parts emitting gas under the influence of the arc heat and a separate snap-action switch mechanism for quick on and off switching, which is accommodated in the switch head Switching on the switch disconnector, a contact is first made on the main current paths, characterized in that the switching mechanism consists of a spring-loaded switch mechanism known per se, consisting of a rocker arm system and a toggle spring, for actuating an actuating rod (12) and for tensioning an actuating rod between the latter in a manner known per se and a switching tube (9) arranged, travel-dependent (16, 17) releasable switching spring (13) for the quick disconnection of the load switching point independent of the snap-action mechanism and that an additional return spring (26) hinged to the drive crank (23 ) for the immediate ge reconnection of the load switching point is planned. 2. Arc extinguishing device according to claim 1, characterized in that the switching tube (9), on which the movable contact piece (8) and a follow-up pin (10) are attached, consists of metal and is slidably arranged in the tube hinge (7) made of gas-emitting material . 3. Arc extinguishing device according to claim 1 or 2, characterized in that the opening spring (13) as a compression spring between an annular shoulder (14) in the switching tube, (9) sliding and articulated to the rocker arm system actuating rod (12) and a collar shoulder (15) of the switching tube (9) is arranged. 4. Arc extinguishing device according to one of claims 1 to 3, characterized in that a spring-loaded pawl (17) for locking the switching tube (9) is provided in the on-switching position, with which a locking ring cam (16) of the actuating rod # (12) works together. 5. Arc extinguishing device according to one of claims 1 to 4, characterized in that the snap-action switching mechanism consists of a rocker arm system consisting of three articulated levers (18, 19, 20) and a tension spring (21) as a rocker spring, the two tilt positions of which are provided by a stop ( 22) are limited. 6. Arc extinguishing device according to one of claims 1 to 5, characterized in that the drive shaft (28) for the Sprungschaltvverk in the housing (3) is rotatably mounted and on the protruding - shaft stub carries an actuating lever (29). 7. Arc extinguishing device according to one of claims 1 to 6, characterized in that the drive crank (23) is attached to the shaft (28 ) which actuates the rocker arm system with two drivers (24 and 25) and the movement of which under the action of the return spring (26 ) is limited by a stop (27).