DE819273C - Arc extinguisher with a differential pumping device - Google Patents

Description

Arc extinguishing apparatus with a differential pumping device There are Arc extinguishers with a differential pumping device in the most diverse Executions known. The differential pumping piston will in most cases go through self propels the arc gas pressure and creates a liquid pressure jet, which is driven at high speed into the arc gas column. It was also already proposed to drive the differential pump piston independently of to use a compressed gas supplied from outside the system for the arc gas pressure. The flow of the pressurized gas is regulated by a control unit in such a way that that the compressed gas has free access to the pump piston during the extinguishing process, and is able to escape freely into the outside air after the end of the extinguishing process.

In contrast to these known designs, the subject matter of the invention works both the arc gas pressure and an external pressure medium are additionally driving on the differential pumping piston. This can be done in such a way that the arc gas pressure acts in the usual way on the large piston area of the differential pump piston and a second piston is provided in the extinguisher which is against the differential pumping piston is supported and driven by the external pressure medium. But it can also do that Foreign gas or a liquid accelerated by foreign gas has direct access to the Find the driving surface of the differential pumping piston.

This new process offers particular advantages. It's easy that adapt foreign pressure medium to the arc gas pressure in its pressure level so that one or the other power source predominantly depending on the level of the breaking capacity the driving force for the pump piston is available represents. At a .Kurzschlussschaltttng the inflow of the external pressure medium is inhibited or. the Pressure medium even temporarily pushed back, while with a low shut-off performance the pump piston is mainly moved by the external pressure medium. The stranger The drive source therefore has a uniform effect on the pump output. Also stands the driving force of the external pressure medium is full from the beginning of the contact separation available so that the arc can be blown with liquid without delay begins as soon as a flushing channel is free for the arc. this is very important when switching off a very small power or when switching off of no-load transformers. Here is the energy released in the arc so small that the pressure increase caused by the evaporation of the liquid in the vicinity of the arc is not sufficient to set the pump piston in motion. The weak arc is generated without being flushed, especially at high voltage drawn out for a long time before it can finally go out. With such a shutdown no-load lines often occur very high overvoltages, which on a Point of the system can cause a breakdown, its short-circuit current then generated a very large amount of steam in the existing very long arc. These causes a pressure surge that can damage the switchgear.

With the new extinguishing method, these disadvantages of a liquid switch avoided with differential pumping pistons. The driving force for the pump piston is available in the form of the external pressure medium from the beginning of the contact separation and independently of the currently prevailing arc gas pressure. The arc will be permanently deleted immediately after the flushing channel has been released and thus the Avoid occurrence of excessive overvoltages.

With this new extinguishing device, you are also able to control the arc to keep completely away from the pump rooms and the contact point along with one Arc extinguishing channel outside the boundary wall of the pumping device in the pressure-free To arrange switch room. This makes it possible that all major pressure fluctuations, especially the dreaded switch-on pressure surges, in the pressure-free switch room can compensate, so that all high pressure loads on the chamber walls stay away. One of the features of the invention is that the contact pin exposed interior of the extinguishing channel only in temporary connection with the drive compartment of the differential pumping piston. The arc gas pressure inside the extinguishing channel can only affect the drive space of the differential pump piston from the moment to transfer, in which the contact pin exposes the connecting channel of the two rooms Has. This temporary application of the arc gas pressure to the differential piston is desirable and also permissible, as the The extinguishing flow through the external power source always runs over the arc can be sustained.

-If the stationary mating contact is designed as a hollow contact, then it is advantageous to also connect the back of the hollow contact to the pump chamber of the differential piston or even better with the third pressure-free, limited by the differential piston To connect the pump chamber and to arrange the hollow contact separately from the extinguishing channel so that that the liquid displaced from this third space or a part of this amount of liquid Flow as unrestrained as possible through the hollow contact to the pressure-free switch room can. This ensures that the exposed by the contact pin in the hollow contact Space is immediately filled and flushed with liquid, which was previously useless had to be repressed. If the interruption arc occurs, the arc root point remains and also any impurities from around the arc in spite of the sudden Pressure increase outside the contact area @ of the contact interior, since it is on hit the liquid content of the hollow contact and be held there.

In the drawing, a switchgear with the listed is an example Features of the invention shown. The cylinder housing of the switch is marked with i, the The lower end cover of the housing is designated with 2 and the upper end cover with 3. A transverse wall 4 divides the chamber of the pumping device from the pressure-free switch room 5 from. In the pump chamber, a differential pump piston 6 is installed, which the pump chamber into a piston drive space 7, into a liquid delivery space 8 for the arc blowing and divided into a third space 9, the fluid content of which is as pressure-free as possible and can escape unrestrained to the pressure-free switch room. The liquid delivery space 8 also contains the return spring io for the pump piston 6. In this exemplary embodiment is the contact point, consisting of the stationary contact i i and the movable one Contact pin 12, arranged outside the pump device in the pressure-free switch room. The back of the stationary hollow contact i i is not, as has been the case up to now, with the pump chamber 8, but via a feed pipe 13 to the low-pressure third chamber 9 of the pumping device in connection. The one in the direction of the switch-off movement of the contact pin 12 lying side of the hollow contact opens freely after the pressure-free switch room. At a certain distance from the stationary contact, seen in the disconnection direction, is an extinguishing channel made of insulating material to be exposed by the contact pin 14 provided in the annular channels 15 directed radially to the longitudinal axis of the channel and 16 merge. The upper end of the extinguishing channel 14 leads to the pressure-free switch room 5. The ring line 16 leads from the extinguishing channel to an enlarged ring channel 17, from which some pipe sockets 18 connect to the narrowing Pumping room 8 manufacture. The ring channel 15 runs through a transverse wall i9 of the switch room to a channel 20 in the cylinder wall i of the switch. These channels represent the Connection between the extinguishing channel 14 and the widening pump chamber 7. In the transverse wall i9 are overflow openings 21 that balance the pressure between the top and bottom of the bulkhead. Also located outside of the switch housing a liquid storage vessel 22 through a pipeline with the expanding pump chamber 7 is in connection .. In the upper cover of the liquid vessel 22 opens into a pressurized gas line in which a control element 23 is provided that regulates the flow of pressurized gas to the vessel. Furthermore is between the pressure-free switch room 5 and the upper part of the liquid storage vessel 22 a connecting channel is arranged in which a non-return member 24 is located, the gas and liquid can pass from the switch room 5, but the pressurized gas from the vessel 22 the passage to the counter is blocked. In addition, in the differential pumping piston 6 yet another piston 25 installed, which is of a Counter spring 26 is loaded and by the external pressure medium against the spring force can be moved in the pump piston.

If the current is to be interrupted, shortly before the contact is separated, the control element 23 is brought into a position in which the pressurized gas has free access to the liquid storage vessel 22. The pressure of the propellant gas is transmitted through the liquid column to the widening pump chamber 7 of the switch, so that the pump piston is under pressure even before the contact separation begins. The differential piston 6 cannot initially move because the contact pin 12 still keeps the outflow channel 16, 17, 18 of the pump chamber 8 closed. The advance piston 25 located in the differential pump piston starts moving immediately with the contact pin adjustment and immediately fills the space exposed by the contact pin in the stationary hollow contact with liquid. If the contact pin leaves the hollow contact ii, an interrupting arc arises between the two contacts ii and 12 in the pressure-free switch room, where the resulting amount of liquid vapor is absorbed and condensed without a significant pressure surge. The piston 25 continues its pumping movement under the influence of the external pressure medium and pushes liquid through the hollow contact ii to the pressure-free switch space 5. The liquid movement present in the hollow contact keeps the arc base and all metal vapors and impurities from the area around the arc away from the inner contact surface, see above that in the event of a later switch-on, a good contact connection between the two current-carrying surfaces and thus a good current transfer to the contact surfaces is always ensured. This is of great importance for trouble-free switch operation. If the contact pin 12 has exposed the annular channel 16 of the extinguishing channel 14, the differential piston 6 can also start its pumping because pressure fluid can pass from the pump chamber 8 over the arc through the lower end surface of the extinguishing channel 14 into the pressure-free switch chamber 5. On its further switch-off path, the contact pin 12 also opens the ring cross-section of the channel 15, through which the arc gas pressure in the extinguishing channel 14 is now transmitted through the channel 2o to the widening piston drive chamber 7. An excessive pressure surge on the piston does not occur here, since the impact is elastically absorbed by the external pressure medium. The external pressure medium is able to withdraw through the container 22. The latter happens without increasing the counterpressure, since the open valve 23 allows the amount of gas that weighs on the liquid level in the container 22 to recede to the pressurized gas container. The external pressure medium therefore has a balancing effect on the piston drive force, all the more so since a certain lower pumping capacity is maintained by the external pressure medium even if the arc gas pressure drops. Instead of a pressurized gas inlet sieve 27, a sliding piston can also be installed in the liquid storage cylinder 22, which piston then prevents any possible passage of liquid through the control element 23. If the contact pin has left the quenching channel 14, the elongated arc burns in the pressure-free switch room 5 and the partial arc in the quenching channel 14 is vigorously flushed so that reliable quenching takes place when the current passes through zero.

When switching off no-load transformers, the current flow is in the arc and thus the evaporation of the liquid is so low that the differential pump piston cannot be moved by the arc gas pressure. In this operating case the pump capacity for the extinguishing agent in full only through the external pressure medium generated and the very weak arc path on one for the operating voltage thoroughly cleaned of sufficient length and filled with fresh insulating liquid, so that too frequent re-ignitions and the occurrence of impermissible overvoltages remain under.

If the switch is closed, the otherwise feared high ones occur Pressure surges do not occur because of the amount of steam caused by the start-up arc can expand unchecked in the pressure-free switch room. The removal of the extinguishing channel. 14 from the stationary contact i i is chosen so that the one present for the switch Mains voltage a starting arc only appears when the contact pin has already closed the flushing channel 16 on its switch-on path. It stays then the differential pumping piston in its initial position, as there is no liquid out the pump chamber 8 can be displaced. The differential piston therefore stands after Switch-on is always available for the switch-off process with the full pump stroke.

If the switch is switched on for a short circuit

Claims (5)

PATENT CLAIM: i. Arc extinguishing apparatus with one by the arc gas pressure driven differential pumping device for generating a jet of liquid for extinguishing the arc, characterized in that a control device known per se (23) the inflow of an external pressure medium to the differential pump device in the Way controls that the pressure medium is additionally driving during the switching process acts on the differential pumping piston. 2. Arc extinguishing apparatus according to claim i, characterized in that a second, against the differential pumping piston more supportive directed; so the contact pin is initially in a short circuit shutdown led only to the upper half of the extinguishing channel 14. With this contact position if the flushing channel 16 is exposed, the arc is extinguished and immediately the contact pin brought back to the on position. If there is a short-circuit current after switching it off and on even further, the final switch-off takes place, with the contact pin up to in its end position is performed. Piston (25) is provided, which is fed through the loaded external pressure medium, additionally drives the differential pump piston. 3. Arc extinguishing apparatus according to claim i, characterized in that the supplied Foreign pressure medium has free access to the drive chamber (7) of the differential pump piston has, with which space also the inside of a made of insulating material and outside the boundary wall of the pumping device in the pressure-free switch room (5) Extinguishing channel (i4) is temporarily connected. 4. Arc extinguishing apparatus in particular according to claim i to 3, characterized in that during the switching the third by the differential piston (6) and the transverse wall (4) limited pump chamber (9) via a stationary hollow contact (ii) is connected to the pressure-free switch room (5). 5. arc extinguishing apparatus according to claim 4, characterized in that a piston (25) is slidably installed in the differential piston (6), which is caused by the external pressure medium is already loaded before the contact separation and from the beginning of the contact pin movement of liquid from the third pump chamber (9) in spite of the standstill of the differential piston (6) displaced.