DE1129589B - High-voltage resistance or load switches for different nominal voltages - Google Patents

Description

The switching principles known today are generally used for each series voltage and rated breaking capacity realized through our own construction. Further differences result from the size of the rated currents. This leads to the range from 10 ... 30 kV, 200 ... 1000 MVA and 400 ... 1000 A has already resulted in an extraordinarily large number of types that are uneconomical to manufacture is. It is also necessary to keep a large number of spare parts in stock.

When investigating resistance switches where the main current is carried after opening one Bypass contact, the current is reduced by a generally rapidly increasing resistance and then the remaining small residual current is interrupted, it has been found that for example, for the power range of 200. . . 1000 MVA with one and the same resistor can get along.

It is known per se, gas pressure switches for different series voltages according to a modular system by joining together identical members in the form of hollow insulators, each one Have switching chamber with an interruption point to build. Such a design has the Disadvantage that with increasing series voltage there is a larger number of switching chambers and interruption points becomes necessary. As the voltage increases, more switching contacts must be actuated, which means greater drive energy and brings with it greater consumption of compressed gas. The larger compressed gas consumption requires in turn, a larger pressure vessel and a higher-performance compressor system.

There is also a pressure gas switch with a base and support attached to it known, wherein the base contains the drive and the post supports the switching chambers.

The invention relates to a high-voltage resistance switch or load switch for various nominal voltages. It consists in the fact that the switch type for the lowest rated voltage, which forms the basic construction cell of a series, consists of a base and a high post insulator attached to it, which carries the fixed contact pieces of a main contact system, and a parallel to the main contact system with connections for impedances or fuses, there is a secondary contact system, that the base also has the drive high-voltage resistance or load switch, which is dimensioned for the contact actuation of the basic construction cell, but which remains the same for the switch types with a higher rated voltage
for different nominal voltages

Applicant:

Siemens-Schuckertwerke Aktiengesellschaft,

Berlin and Erlangen,
Erlangen, Werner-von-Siemens-Str. 50

Dr. Fritz Kesselring, Küsnacht, Zurich,
and Robert Stulz, Oberengstringen, Zurich (Switzerland), have been named as inventors

contains medium, the dielectric strength of the solid insulating parts of the basic cell for the the highest rated voltage, the flashover strength only for the the lowest rated voltage and the main contact system for the highest Current load of the series are dimensioned, and that the base has devices for gas-tight Attachment of an insulating housing enclosing the switching device with which the basic construction cell to set up the switch types with higher nominal voltages is to be added, whereby the outer Flashover path of the insulating housing and the gas pressure prevailing inside it of the respective Nominal voltage are adjusted.

The basic construction cell designed according to the invention can, as already mentioned, with the same Resistance provided can be used for a very large power range. Because the main stream essentially only from the fixed contact pieces, which at the same time represent the connections, and there is a very small power bridge, it makes sense and is economical to have the construction cell the same to be equipped for the highest possible nominal current. To now the resulting from the structural unit Resistance switches whose flashover strength is rated for the lowest series voltage is, in addition to clean indoor facilities, also in dirty plants and open-air facilities as well to be able to use higher voltages, measures are provided in order to be able to use the high-voltage resistance switch in a gas-tight insulating

209 580/325

to accommodate housing that can be filled with a gas, which ensures a higher flashover resistance than air at atmospheric pressure.

Compared to the known, built according to a modular system switch, the switch demonstrates the invention has the following advantages:

a) For the lowest series voltage, for example 10 kV, the largest in terms of number of units Has turnover, only the basic building cell is required.

b) For the higher voltage series, exactly the same basic construction cell is used with the the same switch-off path and the same drive are used. Additionally only comes another bell-shaped insulating body with correspondingly higher external connections and internal gas filling.

c) The individual series of voltages are not created by lining up the same series of voltages Components, but by adding bell-shaped insulating parts, which are, however, among themselves are different according to the nominal voltages. These bell-shaped insulating parts are on are simple and do not contain any moving parts or parts to be coupled with the drive.

The essence of the invention is explained in more detail with reference to FIGS. 1 to 5, FIG. 1 showing the high-voltage resistance switch in its basic form, d. H. as a unit for 10 kV, while FIG. 2 shows a resulting outdoor resistance switch for 30 kV. 3 to 5 schematically show some further exemplary embodiments.

In Fig. 1, 1 means the base, which is in the control wall 2 is inserted, 3 a hollow post insulator corresponding to the row for 10 kV, 4 and 5 the fixed contact pieces of the main contact system, dimensioned for a nominal current of 1000 A, and 6 the movable switching bridge. The dielectric strength between the stationary contacts 4 and 5 is guaranteed up to 30 kV by the insulating piece 7. Its flashover strength corresponds to however, only that of the post insulator. The insulating piece 7 has an I (double-T) profile, the central web of which in the figures is shown in section. Two legs of the profile each grip the fixed contact pieces 4 or 5. The secondary contact system 8 has connections 9 and 10 to which, for example, the Resistancell is connected. Several of the secondary contacts can be arranged next to one another be (see. Fig. 3 to 5). The insulation system 7 with the switching bridge 6 is through the electrodynamic Drive 12 with the fixed coil 13 and the movable metal disk 14 driven. the The switch is triggered in a known manner such that in the fixed coil 13, for example by discharging a capacitor, a steeply rising current pulse is generated, whereupon the disk 14 and thus also the insulating piece 7 and the switching bridge 6 with great acceleration move up. The entire switch is on the releasable one Plate 15 attached; 16 is a sealing surface.

The embodiment according to FIG. 1 represents a resistance switch for 10 kV, 1000 A and rated breaking capacities of, for example, 200 to 1000 MVA. It is assumed that the electrodynamic drive 12 its energy from is fed outside.

FIG. 2 now shows how a 30 kV outdoor switch can be created using simple additions from the structural unit according to FIG. 1 can be produced. In contrast to FIG. 1, the switch is shown here in the open state. The corresponding parts are again with the

ίο the same reference numerals as in FIG. 1 have been provided. The insulating body 20 has been added, which is pressed against the seal 16 with the aid of the flange 21 and with a gas 22 of higher dielectric strength than air under atmospheric pressure is filled so that the switch meets the requirements of the series for 30 kV. As a puncture-proof Gas comes air under increased pressure or an electronegative gas, such as. B. sulfur hexafluoride, under atmospheric pressure or under increased pressure in question. The connections 23 and 24 are now like this high above earth potential, that the test voltage of this series is maintained under open-air conditions. Additionally In the base 1 there are also capacitors 25 and the release system27 that can be swung out around the hinge 26 provided that by lines not shown with the fixed coil 13 of the electrodynamic drive 12 is in connection. The base 1 is through a door 28 after Operator side completed.

Since the structural unit according to FIG. 1 only has sliding contacts 29 and 30 with the connections 23 and 24 is connected, after opening the door 28 and pivoting the release system 27, the actual Switch can be pulled out after loosening the flange 15 towards the operating side. the Checking and any replacement of parts subject to wear is therefore very easy Way possible. Of course, the elements supplying and controlling the drive energy can 25 and 27 already be present in the unit according to FIG. 1, since these parts are generally used for Embodiments of the series remain the same. Often enough, it is only sufficient for low-power switches a smaller number of capacitors.

Fig. 3 shows schematically an embodiment of a switch according to the invention in the form of a so-called Fuse reducer. For the sake of clarity, the corresponding ones are also used here Parts have been given the same reference numerals as in FIG. Instead of resistance 19 the fuse 31 is now connected to the external connections 9, 10 '. Im switched on State, the operating current flows through the main contact system 4, 5, 6. When switching off, the Current from the main contact system initially to the series-connected, initially still closed Secondary contacts 8, 8 'commutated. The latter are then separated by the insulation system 7, whereupon the Current flows through the fuse 31 and is then interrupted.

FIG. 4 shows a current limiter. The resistors 32 and 33, which correspond to the resistors 11 in FIG and 2 correspond, for example, to iron wire. As well as the power from the main contact system is commutated via the secondary contacts on the resistors 32, 33, their resistance increases as a result of the Warming up very quickly, as a result of which the current drops to small values.

Finally, FIG. 5 shows an actual resistance switch. It is appropriately controlled in such a way that that the main contact system is separated when the current passes through zero. Shortly after the current is then commutated to the iron resistor 34 by opening the secondary contact 8. After the current has been reduced accordingly, the final interruption takes place at the secondary contact 8th'.

In addition to the embodiments shown in FIGS of resistance switches according to the invention can also be used for very small powers Constructions without parallel paths to the secondary contacts are used as so-called load switches reach. On the other hand, the iron resistor 34 in FIG. 5 is in the form of a temperature-dependent one Resistance executed, so there is a so-called pre-stage switch.

It can thus be seen that from the design of a resistance switch according to FIG. 1 by simple Additions for the range from 10 ... 30 kV, 400 ... 1000 A and 200 ... 1000 MVA, if only the embodiment is built as a resistance switch according to FIG. 5, around 30 types of indoor switches can be put together, for which a separate construction was previously necessary was. If one takes into account that there are also other variants, as indicated in FIGS. 3 and 4, furthermore Embodiments for polluted plants and open-air systems are possible, so you can see them great advantages that result from this combination of types.

Claims (4)

PATENT CLAIMS: 1. High-voltage resistance or load switch for different nominal voltages, characterized in that the switch type forming the basic construction cell of a series of types for the lowest nominal voltage in a manner known per se consists of a base and a hollow post insulator attached to it, which carries the fixed contact pieces of a main contact system , and a secondary contact system, which is parallel to the main contact system and is provided with connections for impedances or fuses, furthermore the base contains the drive means which are dimensioned for the contact actuation of the basic construction cell, but which remain the same for the switch types of higher nominal voltage, whereby the dielectric strength of the fixed insulating parts of the basic construction cell for the for the stresses occurring at the highest nominal voltage, the flashover strength only for the stresses occurring at the lowest nominal voltage and the main contact system for the highest current stress of the series s, and that the base has devices for gas-tight fastening of an insulating housing enclosing the switching device, with which the basic construction cell is to be supplemented for the construction of the switch types of higher nominal voltages, the outer flashover path of the insulating housing and the gas pressure inside it being adapted to the respective nominal voltage . 2. High-voltage resistance switch according to claim 1, characterized in that the at For switch types with higher rated voltages, provide the insulating housing to be used with connections which are higher according to the required external flashover strength, where these connections via easily detachable contacts, in particular sliding contacts, with the the post insulator arranged contact pieces are connected. 3. High-voltage resistance switch according to claim 1, designed as a wall switch, characterized characterized in that the base is made accessible on the side facing away from the post insulator is. 4. High-voltage resistance switch according to claim 3, characterized in that the Post insulator is mounted on a support plate which is releasably connected to the base that the switching device can be pulled out through the base. Considered publications:
German Patent Nos. 556 469, 570 237;
Swiss Patent No. 239 829. For this purpose, 1 sheet of drawings © 209 580/325 5.62