DE1261930B - High-voltage gas switch - Google Patents

Description

FEDERAL REPUBLIC OF GERMANY

GERMAN

PATENT OFFICE

EDITORIAL

Int. CL:

HOIh

German class: 21c-35/10

Number: 1261930

File number: V 20399 VIII d / 21 c

Filing date: March 23, 1961

Open date: February 29, 1968

The invention relates to a high-voltage pressure gas switch in which both the power disconnection point as well as a voltage separation point connected electrically in series, axially one behind the other in one common, constantly filled with pressurized gas housing are arranged.

Pressure chamber switches are already known in which the power disconnection point has a voltage disconnection point is connected in parallel, the stationary contact of the power disconnection point from one in the switching chamber protruding implementation is carried. However, such switches have due to the Parallel connection of the separation points and because of the required isolation of the stationary contact of the Power separation point with large dimensions compared to the switching chamber wall carrying the counterpotential on.

Furthermore, a switch with a switching chamber that is not constantly filled with pressurized gas is known the power and voltage disconnection point axially one behind the other, are arranged electrically connected in series, the power disconnection point of one Insulating cylinder is surrounded and bridged, on the inside of the common housing of the Separation points located front side, the stationary contacts of the power and voltage separation point arranged are. However, this design leads to interrupter chamber dimensions that are no longer justifiable, as the voltage disconnection point after power cut-off under atmospheric conditions is kept open, with the additional fact that it is necessary to flush the switching chamber spaces will.

The invention is therefore based on the object of arranging the separation points of a pressure chamber switch in such a way that that an optimal dimensioning and design of the switching chamber is made possible.

According to the invention, this is achieved in that the power disconnection point in a manner known per se is surrounded and bridged by an insulating framework, which is on its inside the common housing the end face located at the separation points is provided with a flange, which apart from a contact of the Voltage separation point carries the movable contact of the power separation point, whose movable contact is arranged in the insulating framework. The scaffolding made of insulating material and the flange are used for this Appropriate training both for controlling the power disconnection point and for controlling the voltage disconnection point. The power and voltage disconnection point can also be controlled separately via several Drilled holes in the appropriately trained, high-voltage pressure gas switch

Applicant:

VEB Transformatorenwerk Karl Liebknecht,

Berlin-Oberschöneweide,

Wilhelminenhofstrasse 83-85

Named as inventor:
Walter Gleichmann, Berlin-Koepenick;
Heinz Mäkelburg, Berlin-Karlshorst;
Fritz Paul, Berlin-Oberschöneweide

The existing scaffolding and the flange are made of insulating material.

Arranging the scaffolding made of insulating material has a particularly favorable effect for the accommodation a control resistor. The fact that the structurally strung together for proper fastening Power and voltage separation point for the framework made of insulating material z. B. several If insulating rods are used evenly distributed around the circumference, it is possible to adjust the control resistor to be applied to these insulating rods under favorable conditions. Also is the application of the control resistor on the scaffolding made of insulating material possible in such a way that ζ. Β. a semiconductor between in each case two insulating material segments of the frame is embedded or that the semiconductor is the entire Surrounds the scope of the framework made of insulating material, the semiconductor on the inner and / or outer periphery of the frame can be arranged. In this context, it is particularly advantageous if the scaffolding, which is made of insulating material and bridging the power disconnection point, is made up of such a structure voltage-dependent resistance material is formed. Of course, the control resistor can also be embedded directly into the scaffolding made of insulating material, which is given in particular is when a cast resin is used as the insulating material.

Another advantage arises with the gas pressure switch according to the invention when the required Blow valve in a manner known per se for the power disconnection point in the immediate vicinity of the power disconnection point is arranged. This makes it possible to fill the space between them To keep the blow valve and the power separation point very small, so that the overall dimensions of the switching chamber compared to conventional compressed gas

809 510/247

switches where both the power disconnection point as well as the voltage separation point are arranged in a common switching chamber filled with compressed gas can be further reduced.

According to a further feature of the invention, the movable contact of the voltage separation point be designed as a hollow contact in a manner known per se to increase the residual switching capacity, so that when switching off larger control resistors, those formed during switching off are ionized Gases can flow further into the open through the hollow contact.

Using a representation, this will be explained in more detail on an exemplary embodiment according to the invention explained.

The F i g. 1 shows a gas pressure switch of the invention Type in which with 1 the structurally combined power and voltage disconnection point 2 and 3 receiving switching chamber is designated. The structurally combined performance and span is ao Voltage separation point 2 and 3 provided with a flange 4, which consists of an insulating tube 5 Scaffolding is held. The insulating tubes 5 and the flange 4 are designed so that the controller the separation points takes place. In this arrangement, these insulating tubes are only loaded during of the switch-off process, since the control of the separation points is made so that, after the voltage separation point 3 is open, the power separation point 2 is closed, so that then the insulating tubes 5 are bridged. 7 with the control resistor wound onto the insulating tubes S is designated. 8 shows an opening through which the switching chamber 1 communicates with the pressurized gas boiler stands. The stationary ring contact 9 of the voltage separation point 3 can also be used for this purpose, however then advantageous for the outflow of ionized gases when switching off larger control resistors is used if the movable contact of the voltage separation point is not designed as a hollow contact is. Advantageously, the end face 6 of the switching chamber, which is initially located at the power disconnection point 2 1 detachably arranged so that by removing this wall not only the elements of the power separation point 2, but also those of the voltage separation point 3 are easily accessible.

Of course, in connection with the arrangement according to the invention, the separation points are above the scaffolding made of insulating material also any other design of the switching chamber possible, z. B. as shown in FIGS. 2-4 are shown. All of these switching chambers point towards the after F i g. 1 has the advantage that it is protected from heating caused by the formation of eddy currents in the metal switching chamber wall, are exempt and that the dimensions of the switching chambers compared according to FIG. 1 can be significantly reduced, which is achieved in that the Separation points 2 and 3 comprehensive jacket 10 consists of an insulating material, so that on the fixed Ring contact 9 carrying bushing insulator according to FIG. 1 can be dispensed with. While a prerequisite for all switching chambers is that the power separation point 2 through the insulating frame S is bridged, the power disconnection point 2 blown compressed gas can be directly at the power disconnection point pending, then of course a blow valve, which is not shown here is, must be arranged directly at the power disconnection point and the insulating frame 5 holes 11 must contain, through which the compressed gas in the receiving the power separation point 2, through the Insulating framework S delimiting space 12 flows. Such an arrangement of the Blow valve 13 possible that this closes off the entire space 12, it can then on the holes 11 can be waived. Such an arrangement is shown in FIG. 3 can be seen. To at least that for one Shutdown required pressurized gas is available in the immediate vicinity of the power disconnection point can have, with a paired arrangement of the switching chamber according to FIG. 2 and 3 on the post insulator a pressurized gas reservoir can be arranged between two switching chambers, one such Arrangement is possible that the end faces 6 of the switching chambers are already the end faces of the pressurized gas reservoir represent, or the pressurized gas storage tank is separated from the switching chambers and lies over the switching chambers. Such an arrangement of the compressed gas storage container is also possible when only one switching chamber is arranged on the post insulator.

The F i g. 4 shows such an arrangement of two switching chambers, through which an increase in the Series voltage with respect to the switching chambers according to FIGS. 1 to 3 is reached. With this arrangement the switching chambers is on a metal reinforcement between the post insulators 14 and the jacket 10 been omitted, and the switching chambers are directly on the post insulators 14 with the Ground potential lying, further not shown compressed gas container in connection.

Claims (7)

Patent claims: 1. High-voltage pressure gas switch, in which both the power disconnection point and an electrical voltage separation point connected in series axially one behind the other in a common, housings constantly filled with pressurized gas are arranged, characterized in that that the power separation point (2) is surrounded by an insulating structure in a manner known per se and is bridged at its inside the common housing between the separation points located end face is provided with a flange (4), which apart from a contact of the Voltage separation point carries the movable contact of the power separation point. 2. High-voltage pressure gas switch according to claim 1, characterized in that the insulating frame and the flange have interruptions (11) through which the space that is covered by the insulating framework is included, connected to the interior of the common housing of the separation points is. 3. High-voltage pressure gas switch according to claim 1 and 2, characterized in that the holes provided in the insulating frame extending in the radial direction are or openings that penetrate the insulating framework in the axial direction. 4. High-voltage pressure gas switch according to claim 1, characterized in that in the Isolation frame and in the flange, which is attached inside the common housing of the separation points. is arranged, holes are available through which both the feed separately for both separation points and the discharge of the compressed gas takes place, which is used to operate the power and Voltage separation point is necessary in a known manner required means. 5. High-voltage pressure gas switch according to claim 3 and 4, characterized in that the Insulating frame is formed by a number of insulating tubes which are arranged at a distance from one another are, with the pressurized gas required to operate the separation points via these insulating tubes is supplied or discharged. 6. High-voltage pressure gas switch according to claim 1 to 5, characterized in that the Cylinders made of insulating material or the insulating tubes for applying the control resistor to serve. 7. High-voltage pressure gas switch according to claim 1, characterized in that in order to increase the residual switching capacity, the movable contact of the voltage separation point is designed as a hollow contact in a manner known per se. Considered publications:
German patent specifications No. 884 525, 947 630, 975 887; German explanatory documents No. 1052 501, 532, 1062 788, 1063 682, 1086 780, 581, 1105 949, 1105 950. 1 sheet of drawings 809 510/247 2.68 © Bundesdruckerei Berlin