DE570237C - Arrangement for pre-contact resistors for switches with arc extinguishing by flowing pressurized gas - Google Patents

Description

Compressed gas switches that are used to switch on large transformers, cables and overhead lines or high-voltage motors are used and in which overcurrents or overvoltages can occur when switched on appropriately equipped with protective resistors. These protective resistors are briefly switched on during the switch-on process switched the circuit and short-circuited after switching on. Included Switching on on short circuit, or if the switch is due to an operating or mechanical Error in the pre-contacts remains, the protective resistance increases Is exposed to warming, it must be ensured that this amount of heat is dissipated and the protective resistance is vigorously cooled for the duration of its exposure.

The patent 507 660 already suggests cooling the resistors in the case of compressed gas switches to be carried out by the fact that they are at the moment of switching or be cooled shortly beforehand by the gases used to extinguish the arc. the The invention aims at a further development of this arrangement and relates in particular on the pre-contact resistances in such compressed gas switches, their contacts to each other envelop and sit at the end of an insulating sleeve, inside of which the extinguishing gas flows to the interruption point.

In such switches, an intensive cooling of the pre-contact resistors is used according to the invention achieved in that the same in the interior of the pressurized gas flow through and the switch room forming insulating sheath are arranged. This provides the desired cooling in a simple and convenient manner achieved. Furthermore, the resistor is prevented from being burned through with certainty its overload capacity increased.

The new arrangement represents a significant advance over the oil switch generally used because of the oil cooling of the resistors known arrangement due to lack of oil circulation, the cooling is often inadequate and also severe damage to the switch, e.g. B. Oil switch explosions, in one Defects in the resistor can occur. In contrast to this, in the arrangement according to FIG of the invention by the fast flowing pressurized gas the resistance among all

Circumstances intensely chilled, and even if a resistance simmered through and attached If a standing arc should form him, there is still no risk of explosion because yes, in contrast to oil, the compressed gas used as a coolant is neither flammable nor flammable is explosive.

The design and arrangement of the protective resistances inside the druckgasto flow through switch shell can be done in different ways. You can z. B. form the moving main contact of the gas pressure switch hollow and the resistance arrange inside the hollow contact, the contact for the purpose of cooling the resistor is blown through by pressurized gas. Instead, you can also use the resistor from several concentric tubes, strips or produce wires and the same in the switch room in a radial or concentric manner Arrange position to the moving pin-shaped contact.

Exemplary embodiments of the invention are shown in the drawing. Fig. 1 represents a Arrangement in a gas pressure switch with \ ^ orkontakt and protective resistor. The The nozzle ι is carried by the insulator 2. The hollow contact 3 with the power supply 4 is notched at 31 at its upper end. The pre-contact takes place in this gap 7, which is connected to a tube 6 made of resistance material, space. The resistance tube 6 is in the hollow contact 3 and conductively connected to the power supply pin 4 via the support fitting 5. The pre-contact 7, which has a larger looping in the nozzle 1 as the Hauptkontakf 3, is provided with a burn-off piece 8, which is made of heavy may consist of vaporizable material. The flow of pressurized gas flowing through the pipe 3 and the resistance tube 6 flows therethrough, takes that developed by the resistance Warmth and has a cooling effect on it. The extinguishing of the interruption arc also takes place through the pressurized gas flowing in from below in the direction of the arrow.

In Fig. 2 an arrangement is drawn in which the hollow main contact 3 and the pre-contact 7 each have a special nozzle 1 and 10. These nozzles are united and carried by the post 2. The resistance tube 6 and the contact 3 have their power supply via the support fitting 5 by means of the pin 4. At the upper end of the resistance tube 6, the pre-contact 7 is attached, which has a larger looping than the main contact 3. In the resistance tube 6 openings 11 are provided through which the compressed gas flowing through the resistance tube 6 exits.

The resistance is so washed around both inside and outside by the compressed gas and thereby energetically chilled. The interruption points are blown out by the Compressed gas flowing in from below. The auxiliary contact 7 can be hollow, so that also through him Pressurized gas escapes at the top.

Fig. 3 shows an arrangement in which the pre-contact is arranged below the nozzle contact 1. The nozzle 1 is carried by the support 2, which is provided at its lower end with the power supply 18 for the movable contact. The resistor 6, which here consists of several concentric resistance tubes connected in series at 12, lies between the nozzle 1 and the nozzle-shaped pre-contact 14. The compressed gas for cooling or the resistor is supplied from the tube 16. The flowing pressurized gas then passes through the channel 15 to the point of interruption. The nozzle-like pre-contact 14 is carried by the insulating tube 13. When the switch is switched on, the contact pin 4 short-circuits the resistor 6 between the nozzles 1 and 14. If the switching pin 4 is moved downwards, when it leaves the nozzle contact 1, the short circuit of the resistor 6 go is canceled and the interrupting arc created between the contacts 1 and 4 is extinguished by compressed gas, which flows through the tube 16, through the resistor and through the channel 15 of the nozzle 1 flows towards it. The current flow is then as follows: power supply 18, contact pin 4, pre-contact nozzle 14, resistor 6, nozzle 1. In the further course of the switch-off movement, the contact pin 4 also leaves the nozzle-like pre-contact 14 and pulls the final interrupting arc between the contacts 4 and 14. This is deleted by pressurized gas which flows from the tube 17 through the insulating tube 13 and the nozzle-like pre-contact 14. In order to prevent the blown arc from short-circuiting the resistor 6 by bridging the nozzles 14 and 1, the blowing through the pipe 16 can be carried out at a higher pressure than that from the no. that it envelops the arc emerging from the pre-contact 14. To achieve this, it is necessary, the channel 15 in the same direction as possible and shall be placed in n ₅ slight inclination to the switching pin. 4 Instead of the resistance tubes 6 shown, any other embodiment of the resistor can of course also be used, e.g. B. Resistance bands or resistance wire. When switching on, the circuit is between the power supplies

18 and ι initially switched on via the resistor 6, which is then short-circuited in the further course of the switch-on movement.

In Fig. 4 an arrangement is shown in which the resistor 6 is not directly combined with the main switch, but has a special switch for short-circuiting. The resistor 6 is arranged in a hollow support 19 and lies between the nozzle 14 and the connecting or air guide piece 28. It is normally short-circuited by the contact pin 20. The main switch is formed from the nozzle 1, the support 2 and the contact pin 4 and is also attached to the air supply piece 28. The two switch pins 4 and 20 can be specially connected by a busbar in order to relieve the material of the guide piece 28. The Schaltao pins are moved by the shafts 23 and 24 via insulating connecting rods 21 and levers 22. The whole arrangement is carried by the hollow post ZJ, which is fastened on the air supply pipe 26. The air supply pipe 26 is mounted on the framework 25. The shafts 23 and 24 are moved either by a common drive or by separate drives. The switched-on position is shown. The power connections are at the nozzles 14 and 1; the current flow goes from the nozzle 14 via the movable contact 20, the sliding contact 18, the air supply piece 28 or a special busbar, the right sliding contact 18 and the switching pin 4 after the nozzle i. If short circuits or overcurrents occur, the shaft 23 is controlled by a special relay, moves and cancels the short circuit of the resistor 6. The resulting interruption arc is extinguished by the compressed gas flowing through the resistance in the direction of the arrow. Here, too, the resistor 6 consists of several concentric tubes made of resistor material, which are connected in series by connecting pieces 12. Any other form of resistance can of course also be selected here. When the short-circuit of the resistor is removed, the current path is: 14, 6, 20, 18, 28, 18, 4 and i. As long as the resistor is switched on, it is cooled by the flowing compressed gas. Depending on the duration or size of the short circuit, the shaft 24 can also be moved after a certain time, whereby the current between the contacts 1 and 4 is interrupted. The resulting arc is extinguished by the pressurized gas flowing in through the support 2. The arrangement can be such that after the short circuit subsides or disappears, the resistor 6 is short-circuited again without an interruption taking place between contacts 1 and 4. If the short circuit persists, however, the current between contacts 1 and 4 is interrupted The resistor 6 can also be set up in such a way that its short-circuit is gradually canceled by moving the switching pin 20, so that a resistance variation is possible by rotating the shaft 23. When switching on, the switching pin 4 is switched on first, whereby the short-circuit of the resistor is canceled The switch-on therefore takes place via the resistor 6. Only in the further course of the switch-on movement is the resistor 6 also short-circuited can be used by several relays (current and time relays) or by depend on the interaction of these relays. The timing of the shifts can also be regulated by mechanical coupling of the drives. By means of such a device, the reactances can be replaced and current attenuation can be carried out by the protective resistor 6 in a certain way as a function of the network conditions. The assembly of the resistance switch and the main switch can be done in any way. It is not absolutely necessary for them to be assembled into a unit; rather, a connection between them and their drives can also be made electrically in a simple manner. It only has to be ensured that the short circuit of the resistance switch is eliminated when the main switch is switched on, which can easily be achieved by means of a corresponding interlock. If necessary, the pressurized gas used to cool the resistor can also be given a higher pressure (higher flow rate - greater cooling capacity) or the pressurized gas used to cool the resistor can be pre-cooled in special devices (refrigerants). Gases that are suitable for dissipating particularly large amounts of heat can also be used to cool the resistor. The resistance itself can be made relatively small as a result of this cooling.

In Fig. 5 an arrangement is shown in which the resistor 6 from several There is concentric tubes and the hollow main contact 4 surrounds. The outer resistance tube is extended towards the top as a pre-contact iao tube 32 and lies on the nozzle 1 at. The hollow contact 4 has its counterpart

contact in the pin 29, which is carried by the nozzle 1 via ribs 30 and is in conductive connection with it. The looping of the pre-contact tube 32 is greater than that of the contact tube 4. Power is supplied to the contact tube 4 through the sliding contact 18. The nozzle 1 and the power supply 18 are carried by the support 2. The pipe contact 4 has openings 34 and 33 through which pressurized gas can enter it. In the switched-on position shown, the resistor 6, which is carried by the contact tube 4, is short-circuited. If the pipe contact 4 is now moved downwards when switching off, the short circuit of the resistor between the fixed pin 29 and the movable contact 4 is first canceled. The resulting arc is extinguished by pressurized gas which flows out through the pipe contact and along it. During this time, compressed gas flows through the resistor and is cooled. Only in the further course of the disconnection movement is finally interrupted between contacts 1 and 32, the final interruption arc also being extinguished by the pressurized gas flowing in from below. On power up the Vorkontaktrohr 32 first comes into contact with the nozzle 1, the resistor is turned on, then in the other \ erlauf ^r of the switching-on to be short-circuited.

Fig. 6 shows an arrangement in which two nozzles are concentric to the switch pin 4 are arranged. The nozzle 1 is supported by the hollow post 2. In the Nozzle ι the pre-contact nozzle 14 is arranged, in which the switching pin 4 moves. the Pre-contact nozzle 14 is carried by tube 36. The resistor 6 is between the Nozzle 14 and the nozzle 1. The current is transmitted through in the case shown the sliding contact 37, which is held by the armature 35, which also carries the resistor will. .The fitting 35 is held by a support 39, which in turn of a fitting to which the power supply 18 is attached is carried. At this Fittings 40 are attached to stops. The tube 36 is 38 pieces by means of the insulating and the bridge 41 moves. The latter is suspended from the part 44 by springs 42 are pressed against the stop 43 of the switching pin 4. The drive engages the insulating tube 45.

The switch-off movement takes place as follows: The switching pin 4 is moved downwards by means of the pipe 45 and takes the pipe 36 and the pipe contact nozzle 14 with it via the springs 42. The short circuit of the resistor between the nozzles 14 and 1 is canceled and the resulting arc is extinguished by the pressurized gas flowing in from below. This pressure gas also cools the resistor. In the further course of the switch-off movement, the bridge 41 comes to rest against the stops 40, and the movement of the pre-contact nozzle 14 is inhibited in the most favorable extinguishing position. The contact pin 4 continues to move and interrupts the current between the contacts 4 and 14, where the final arc is drawn. Also this w ^r ith erased by the incoming pressure from below gas. The shifting pin 4 moved on has tensioned the springs 42. The end interruption takes place with the upstream connection of the resistor 6, which is cooled during the switching process. By suitably shaping the pre-contact nozzle 14, it is possible to prevent the final interruption arc from short-circuiting the resistor 6. When switching on, ie when the switching pin 4 moves upwards, the pre-contact nozzle 14 with the bridge 4i remains under the action of the springs 42 on the stop 40 until the stop 43 takes the bridge 41 and thus the pre-contact nozzle 14 upwards. Since there is an interruption between the contacts 14 and 1 at this point in time, the resistor 6 is initially connected upstream. Only in the further course of the switching movement is the resistor short-circuited between contacts 14 and 1. The stop 40 can be made adjustable. The springs 42 must be so strong that they surely overcome the contact friction between the contacts 4 and 14. The resistor 6 can be designed as desired.

In Fig. 7 an arrangement is drawn in which the pre-contact 7 in the extension of the switching pin 4 is attached. The pre-contact, 7, which is ribbed on the Nozzle ι is applied, is carried by a bolt 53 to which the resistor 6 is connected is. The bolt 53 is enveloped by the insulating tube 52 and carries the main contact 47, which engages in the enlarged part of the nozzle 1. The main contact 47 carries the ring 48 with ribs, on which both the resistor 6 and the power supply rails 49 are attached. These are connected to the support piece 50, which is carried by the power supply piece 4. The resistor 6, which consists of several concentrically arranged tubes, is Also carried by the power supply tube 4 via the insulating tube 51. In the switched on The position is the resistor, which is connected between contacts 7 and 47 is short-circuited. When leaving

switch the power supply bolt 4 is moved down, the resistance short circuit canceled between contacts 46 and 47; the resulting arc is through the from. below, incoming pressurized gas either deleted or from the main contact 47 handed over to pre-contact 7. During the further course of the switch-off movement, between contacts 7 and 1

to with an upstream resistor 6 the final interruption arc pulled and extinguished by the pressurized gas flowing in from below. When switching on comes first the contact 7 engages with the nozzle 1, the resistor is connected upstream and becomes only short-circuited in the further course of the switch-on movement.

In Fig. 8 an arrangement is shown in which the pre-contact 7 is formed in a ring and is arranged concentrically to the switching pin 4. Between the pre-contact and the main contact is the resistor 6, which is from the support armature 50 is worn. This is attached to the insulating tube 52, which also the main contact 4 carries. A second nozzle 10 is arranged concentrically in the nozzle 1, in which the main contact pin 4 engages. Will the latter with the resistance and the Precontact 7 moved down, the resistance short circuit between contacts 4 and 10 are canceled because the pre-contact has a larger looping. The resulting arc is extinguished by the compressed gas flowing through the resistor. In the further course of the The switch-off movement is then the final arc between the pre-contact 7 and the nozzle 1 drawn. When switching on, the resistor is initially connected upstream, which is followed by The course of the switch-on movement is short-circuited. The blowing of the interruption points and the resistor, which can be of any shape, is cooled by that of the support 2, that of the nozzle 1 and 10 carries, flowing through compressed gas.

The resistance itself, which, as I said before, either consists of pipes or pipes Consist of resistance material, or of resistance strips or the like. Be constructed can either participate in the switching movement or firmly in the switch or in the Pressurized gas supply pipes lie. If necessary, the resistance can also be omitted build up voltage-dependent resistance material. Likewise, one can face the resistance give a certain capacitance or connect the resistor to a capacitor during the switch-off, so that the Capacitor is parallel to the switching point.

If necessary, capacitor and resistor can be combined and together with Blow compressed gas. This can easily be achieved in that one of the coverings of the Capacitor made of resistance material and connected in series and in the Interstices plates o. The like. Arranges as a second layer of the capacitor.

Claims (8)

Patent claims: I. Arrangement for pre-contact resistors in switches with arc quenching by flowing pressurized gas, the contacts of which envelop each other and sit at the end of an insulating sleeve in which Inside the pressurized gas of the interruption point flows, according to patent 507 660, through it characterized in that the resistors (6) inside the pressurized gas flowed through Insulating sleeve (2) are arranged. 2. Arrangement according to claim 1 for gas pressure switch with movable hollow contact, characterized in that the resistor (6) is arranged in the hollow main contact (3) through which compressed gas is blown is (Fig. 1). 3. Arrangement according to claim 1, characterized in that the resistor 6. Consists of one or more concentric tubes, strips or wires arranged in the switch room that they are radial or concentric to the switching pin (4) (Fig. 3 "). 4. Arrangement according to claim 3, characterized in that both for the Main contact (4) as well as for the pre-contact (7) switching the resistor (6) each have a special nozzle contact (i or 10) is provided, the two nozzle contacts preferably combined in this way are that they surround each other concentrically (Fig. 2 and 8). 5. Arrangement according to claim 3, characterized in that the resistance (6) switching pre-contact (14) arranged below the main contact (i) is and that each one blowing (16 and 17) for the resistance and for the final interruption arc are provided, of which the pressure gas cooling the resistor is preferably one higher pressure (Fig. 3). 6. Arrangement according to claim 3, characterized in that the pre-contact (7) is arranged in the extension of the main contact (47), such that the arc during switch-off due to the compressed gas blowing from the main contact (47) migrates after the pre-contact (7) (Fig. 7). 7. Arrangement according to claim 4, characterized in that the two Move the nozzle contacts (1 and 14) in this way borrowed are arranged that in the first part of the disconnection movement of the resistance short circuit by the simultaneous separation movement the inner nozzle (14) with the switching pin (4) against the outer nozzle (1) is canceled and then the switching pin (4) alone moves into the end position, with the movement of the inner Nozzle (14) in the most favorable extinguishing position, in particular by means of stops (40, 41) is inhibited (Fig. 6). 8. Arrangement according to claim 7, characterized in that the inner nozzle (14) is taken along by the switch pin (4) preferably via springs (42) ig (Fig. 6). 1 sheet of drawings