EP0466048A2 - Fault-current interruption switch - Google Patents

Abstract

The fault-current interruption switch is preferably provided for transformer branches in ring cable switching installations. It represents a self-sufficient device, accommodated in a closed housing, having a vacuum switching chamber (1), a converter (4), a magnetic trip device (5), a switch-off spring (9) and an interlock (10) which can be released in the event of a disturbance. After each disturbance interruption, the vacuum switching chamber (1) can be switched on again via a screw spindle (18), and the switch-off spring (9) interlocked again. An extension (25) of the shaft of the moving switch contact (1b) transmits the switching movement to the exterior where it enables a switch position indicator or, via connecting means, the tripping of an associated isolating or load switch (32a). The secondary coil (4b) of the converter (4) and the ring coil (5a) of the magnetic trip device (5) are connected in series without using an external energy source. When a lower disturbance current level is reached, the induced secondary current is used to operate the magnetic trip device (5) and hence unlocks the interlock (10). The switch-off spring (9) then switches the vacuum switching chamber off. Once the disturbance has been remedied, the vacuum switching chamber (1) is switched on again via the screw spindle (18). Because the switching device according to the invention contains a vacuum switching chamber (1), it is able to interrupt an unlimited number of disturbances without having to gain access to the interior of the switching device. It can thus be installed inside the encapsulation of gas-insulated switching installations and is thus at the same high insulation level as the means of operation which are in the gas atmosphere. On the other hand, the housing of the switching device according to the invention can be designed in a gas-proof manner so that its internal functions are not affected by environment influences such as corrosion or humidity etc. when used in air-insulated installations. <IMAGE>

Description

The invention relates to a switching device for interrupting fault currents, preferably for transformer branches in medium-voltage switchgear according to the preamble of the first claim.

Such switching devices are preferably used in ring cable switchgear, which generally consist of two ring line panels and at least one switch panel for a transformer feeder. In the CALOR-EMAG publication "Switchgear for Local Distribution Stations with Vacuum Circuit Breakers"; Klaus Böttger and Bruno Schemann, reprint from electrotechnical magazine volume 106 (1985) issue 10, describes a switchgear with the known switching device. The ring cable outlets are each equipped with a load switch and the transformer outlet with a vacuum circuit breaker. The latter takes over the short-circuit protection for this branch in conjunction with an overcurrent relay fed by a current transformer.

The switchgear mentioned, which is gas-insulated with SF6, is considered to be fully insulated, since HH fuses are no longer provided outside the enclosure for short-circuit protection. In addition, it is considered to be maintenance-free, since after the interruption of a short-circuit current by a remotely controllable reclosure of the circuit breaker, the operation again can be recorded without having to intervene to replace equipment, such as the fuses. The lack of HV fuses also excludes other sources of error, such as: presence of one
critical current range in which a fuse has not yet responded or only after a very long melting time and in which there is therefore a risk of overheating and explosion. In addition, a strong spread of the fuse characteristics and an overload of the load switch in the limit area of the fuse, among other things, must be observed.

On the other hand, in the specified switchgear, the vacuum circuit breaker must have the full, e.g. according to the valid VDE regulations have fixed insulation properties and the design of the contacts and the energy storage are able to switch on short-circuit currents without welding.

In the connection area, ie outside the encapsulation of the switchgear, sufficient space must also be provided for the required cable conversion converters. The overcurrent relays are also to be subjected to routine monitoring checks at certain intervals, which is only possible if the feeder is disconnected. With the known switching device, a three-phase interruption of the feeder is always carried out even in the case of single-phase faults, although in many cases it would be advantageous to maintain a two-phase emergency operation. This applies above all to rigidly grounded networks, such as those used in many overseas countries. If the known switching device is used in an air-insulated switchgear, all of its elements are fully exposed to the environmental climate.

The invention has for its object to develop a switching device that can be used as a single-phase, self-sufficient equipment for repeated interruption of short-circuit currents. In addition, all elements in the switching device should be fully protected against the environmental influences, that is to say also against corrosive climates.

The object is achieved by a switching device according to the characterizing features of the first claim.

The switching device according to the invention contains all functionally important elements in a single-phase housing and is therefore suitable for intermittent interruption of fault currents. In addition, the housing can be made gas-tight, so that the use of the protective device according to the invention also results in a significant improvement in the service life of air-insulated switchgear, especially in a humid or corrosion-prone environment.

The switching device according to the invention is self-sufficient because it contains an energy store and a release system, as well as a reclosing device, which can also be easily operated from the operator side in encapsulated gas-insulated switchgear. Due to the built-in vacuum interrupter, the switching device has an almost unlimited service life.

Appropriate embodiments of the inventive concept are specified in the subclaims.

• Figur 1: Schaltvorrichtung im Schnitt in eingeschalteter und und ausgeschalteter Stellung.
• Figur 2: Einbau der Schaltvorrichtung in einer metallgekapselten, gasisolierten Schaltanlage; (einphasige Darstellung)
• Figur 3: Schaltschema des Sekundärkreises innerhalb der Schaltvorrichtung.
• Figur 4: Schaltschema des Sekundärkreises mit Kapazität.
• Figur 5: Schaltvorrichtung mit gewickeltem Kondensator.
• Figur 6: Schaltvorrichtung mit Plattenkondensator.

For a better understanding of the invention, reference is made to the following drawings:

• Figure 1: Switching device in section in switched on and and off position.
• Figure 2: Installation of the switching device in a metal-enclosed, gas-insulated switchgear; (single-phase representation)
• Figure 3: Circuit diagram of the secondary circuit within the switching device.
• Figure 4: Circuit diagram of the secondary circuit with capacity.
• Figure 5: Switching device with a wound capacitor.
• Figure 6: Switching device with a plate capacitor.

A particularly advantageous embodiment of the inventive concept is shown in FIG. The housing of the switching device according to the invention has a cylindrical shape and is divided into two parts inside. In the upper room there is the vacuum interrupter 1, the fixed contact 1a of which is connected to the connector 2 via the conductor spiral 23. With the help of the spiral-shaped conductor 23, a magnetic field is generated, which runs almost parallel to the switch axis in the open contact gap between the switching contacts 1a and 1b and thus improves the switching capacity of the vacuum switching chamber in a known manner. Subsequent to the partition 8, which divides the housing into two parts, is the second room, in which the current transformer 4, the magnetic release 5, the opening spring 9 and the latch 10 are housed.
The second room is closed by the second connector 3. The essential part of the first space is encased by the insulating tube 6, while the second part of the housing is closed off by the metal tube 7. In this way, when the switching chamber is open, the recurring voltage at the switching contacts is present at the porcelain tube of the vacuum switching chamber 1 as well as at the ends of the insulating tube 6. Because inside the Housing there is an environment free of contaminants for the vacuum interrupter 1, the length of the ceramic tube can be significantly smaller than the length of the insulating tube 6, which can also be exposed to unfavorable environmental influences.

The current transformer 4 consists of a ring core 4a and a secondary coil 4b, while the shaft of the movable switching contact 1b or its extension 25 serves as the primary conductor. The latter is connected to the second connection piece 3 via a sliding contact 24 and is therefore flowed through by the primary current during operation. The magnetic release 5 includes a ring coil 5 and a ferromagnetic body 5b surrounding it on three sides, the lower leg of which is designed such that it has a minimal air gap with respect to the magnet armature 5c which can be moved in the vertical direction. The latter is under the action of a return spring 14, which presses it into its rest position when the ring coil 5a is not energized, forming the air gap 26 in the vertical direction relative to the ferromagnetic body 5b (left side of FIG. 1). The current transformer 4 and the magnetic release 5 form an annular gap with respect to the extension 25, in which in the present example the switch-off spring 9, which is supported with its upper end on the partition 8, is arranged. The lower end of the switch-off spring 9 rests on the pressure piece 10b, which in turn is supported over an inclined surface by means of the clamping bodies 10a in the axial direction on the support plate 10c and in the radial direction on the magnet armature 5c (left side of FIG. 1). On the pressure piece 10b, the lower end of the contact force spring 12 is also supported via the tube 11, which are designed as plate springs in the present example and the upper end of which acts on the shaft of the movable switching contact 1b of the vacuum interrupter chamber 1 via the shoulder 21. The pin 15 attached in the extension 25 ensures that the two switching contacts 1a and 1b in the switched-off state do not exceed the stroke h. The pin 15 interacts either with the lower surface of the pressure piece 10b or, as drawn in FIG. 1, with a groove 30 machined into the pressure piece (right side of FIG. 1). At the lower connection piece 3 there is a screw spindle 18, with the aid of which the vacuum interrupter 1 can be switched on again after each power interruption and the opening spring 9 can be tensioned until it is latched. The screw spindle in the tensioned position of the opening spring 9 is drawn on the left side of FIG. However, the switching device according to the invention is only ready for switching after turning the screw spindle 18 back into the starting position, namely when the required distance between the lower surface of the pressure piece 10b and the upper edge of the screw spindle 18 has been established. In order to enable easy assembly of the switching device according to the invention, it is advisable to screw the lower connector 3 into the metal tube 7.

In the simplest embodiment of the switching device according to the invention, it is possible to dispense with the attachment of a spiral conductor 23 for generating an axial magnetic field. No additional external energy source is required for the secondary circuit. Rather, the secondary winding 4b of the current transformer 4 is connected in series with the ring coil 5a.

• a) Induktion eines entsprechenden Sekundärstroms in der Sekundärwicklung 4b, der gleichzeitig in der Ringspule 5a ein magnetisches Feld im ferromagnetischen Körper 5b induziert. Dieses wirkt auf den Magnetanker 5c und zieht diesen entgegen der Kraft der Rückstellfeder 14 in den Luftspalt 26, bis der Magnetanker 5c mit der Unterkante des ferromagnetischen Körpers 5b in Berührung kommt.
• b) Die nun nicht mehr in radialer Richtung abgestützten Klemmkörper 10a werden von der Schrägfläche des Druckstücks 10b nach außen bewegt und geben den Ausschalthub des Druckstücks frei.
• c) Unter der Wirkung der Ausschaltfeder 9 bewegt sich das Druckstück 10b bis zu einem nicht dargestellten Anschlag nach unten und nimmt dabei über die Nut 30 und den Stift 15 den beweglichen Schaltkontakt 1b mit, bis der Schalthub h zwischen den Schaltkontakten 1a und 1b erreicht ist.
  Die Ausschaltung ist damit vollendet.
  In Figur 1 ist auf der linken Seite der eingeschaltete und auf der rechten Seite der ausgeschaltete Zustand der Schaltvorrichtung dargestellt. Da die Verlängerung 25 bzw. der Schaft des beweglichen Schaltkontakts 1b die untere Begrenzungsfläche des Anschlußstückes 3 durchdringt, kann die Stirnfläche 25a entweder mit einer Anzeigevorrichtung für die erfolgte Ausschaltung, oder mit einem Mechanismus versehen sein, mit dessen Hilfe ein zugeordneter Trennschalter in die Trennstellung bewegt wird. Dies kann durch ein mechanisches Gestänge zum Ausschalt-Energiespeicher des Trennschalters erfolgen oder über einen Hilfskontakt, der den Ausschalt-Energiespeicher durch einen elektrischen Impuls zur Auslösung bringt.
  Im weiteren Verlauf wird nun die Wiedereinschaltung der erfindungsgemäßen Schaltvorrichtung beschrieben:
• d) mit der Schraubspindel 18 erfolgt eine Aufwärtsbewegung des Druckstücks 10b, bei der gleichzeitig die Ausschaltfeder 9 gespannt und die Schaltkontakte 1a und 1b zur Wiederanlage gebracht werden.
• e) nach erfolgter galvanischer Berührung der Schaltkontakte 1a und 1b wird im weiteren Verlauf der Drehung an der Schraubspindel 18 die Verklinkung 10 in ihre Sperrstellung gebracht.Dies geschieht mittels der auf den Magnettanker 5 c wirkenden Rückstellfeder 14, wobei die Klemmkörper 10 a über die schräge Fläche 29 in ihre Ausgangsstellung unter die schräge Fläche des Druckstücks 10b bewegt werden. Während dieses Vorganges stellt sich zwischen Nut 30 und Stift 15 ein kleiner Überhub ein, der zur betriebssicheren Erzeugung der erforderlichen Kontaktkraft durch die Kontaktkraftfeder 12 benötigt wird.
• f) die Schraubspindel 18 wird in Ihre Ausgangsstellung zurückgedreht, um den für eine weitere Ausschaltung erforderlichen Freiweg für das Druckstück 10b herzustellen.

If an interference current occurs in the primary circuit, the following operations take place in succession in the switching device:

• a) induction of a corresponding secondary current in the secondary winding 4b, which simultaneously induces a magnetic field in the ferromagnetic body 5b in the toroidal coil 5a. This acts on the magnet armature 5c and pulls it against the force of the return spring 14 into the air gap 26 until the magnet armature 5c comes into contact with the lower edge of the ferromagnetic body 5b.
• b) The clamping bodies 10a, which are no longer supported in the radial direction, are moved outwards from the inclined surface of the pressure piece 10b and release the switch-off stroke of the pressure piece.
• c) Under the action of the opening spring 9, the pressure piece 10b moves down to a stop, not shown, and takes the movable switching contact 1b with it via the groove 30 and the pin 15 until the switching stroke h between the switching contacts 1a and 1b is reached .
  The shutdown is now complete.
  1 shows the switched-on state on the left side and the switched-off state on the right side. Since the extension 25 or the shaft of the movable switching contact 1b penetrates the lower boundary surface of the connecting piece 3, the end face 25a can either be provided with a display device for the disconnection that has taken place, or with a mechanism with the aid of which an assigned disconnector moves into the disconnected position becomes. This can be done by means of a mechanical linkage to the switch-off energy store of the disconnector or via an auxiliary contact which triggers the switch-off energy store by means of an electrical pulse.
  The restart of the switching device according to the invention will now be described in the further course:
• d) with the screw spindle 18 there is an upward movement of the pressure piece 10b, in which the switch-off spring 9 is simultaneously tensioned and the switching contacts 1a and 1b are brought back to the system.
• e) after the galvanic contact of the switching contacts 1a and 1b has taken place, the catch 10 is brought into its blocking position in the further course of the rotation on the screw spindle 18 return spring 14 acting on the magnet armature 5 c, the clamping bodies 10 a being moved over the inclined surface 29 into their starting position under the inclined surface of the pressure piece 10 b. During this process, there is a small overstroke between groove 30 and pin 15, which is required for the reliable generation of the required contact force by the contact force spring 12.
• f) the screw spindle 18 is turned back into its starting position in order to produce the free travel required for the pressure piece 10b for a further deactivation.

As a further feature of the invention, the screw spindle 18 can be designed such that, in addition to its function as a switch-on mechanism for the vacuum switching chamber 1, it also serves as a stop for the pressure piece 10b during each switch-off process.

In Figure 1 it can also be seen that the connectors 2 and 3 have pads 2a and 3a, which can be used as an adapter for the terminal contacts of HV fuses. However, other connection surfaces can also be used in the same way.

With the switching device according to the invention, for example, a ring cable switchgear according to FIG. 2 with two cable connections in the lower part of the encapsulation and with a transformer branch in the upper part, in which the residual current protection is integrated into the encapsulation, without using a complete functional circuit breaker got to. Since the switching device according to the invention is a self-sufficient unit which does not require any external energy and in which no replacement of components is required after the fault current has been interrupted, it can be fully incorporated into the encapsulated switching insert. In this case, the same high level of insulation applies to them as for all other equipment installed in the switchgear.

The ring cable switchgear system according to FIG. 2 has, as an example, two three-position switches 32 in its lower part, with which the ring cable can be connected to the busbar 37 or with which each individual cable can be disconnected or grounded. The busbar 37 is connected at the top to a further three-position switch 32, to the switching contacts of which the switching device according to the invention is connected to interrupt fault currents. This switching device is constructed via two clamping contacts 35 and associated insulators on the encapsulation 31; the switching device is oriented so that the second connector 3 faces one of the walls of the encapsulation. The screw spindle 18, not shown, is extended by the insulating shaft 19, which is guided gas-tight to the outside of the switchgear. With your help, either by hand or with a motor drive 34 after the fault current has been interrupted, the switching device 33 can be switched on again or the switch-off spring 9 can be tensioned and latched.

The switching device according to the invention is a single-phase switching device. The end face 25a (not shown) (see FIG. 1) of the switching device 33 according to the invention can be connected to the associated three-position switch 32 by means of a linkage 36 in order to generate a disconnection of the branch after a fault current interruption. In networks with rigid star point earthing or if this is necessary for other reasons, this three-position switch should also be equipped with single-phase actuation.

FIG. 3 shows how the connection between the three single-phase switching devices 33 and a three-phase switch-disconnector 32a takes place by means of an electrical control, and fault current interruptions in one phase are not must lead to the disconnection of the load break switch 32a, but only a two- or three-phase fault current interruptions leads to the final disconnection of the circuit. Each movable switch contact 1b of the switching device 33 is connected to a two-pole auxiliary switch 39 arranged outside the encapsulation 31. The auxiliary switches 39 of all three phases are connected to one another in such a way that an auxiliary contact of two phases is connected in series with one another and is connected to the shunt release of the energy store 38. The energy store can be switched off arbitrarily both via the button 41 and the energy source 40 and, in the event of a fault, via the auxiliary switch 39. The connecting lines between the auxiliary switches 39 of the individual phases are switched so that the shunt release of the energy store 38 is only live when the vacuum interrupters 1 have been interrupted in two phases. In the case of a single-phase interruption, only one contact auxiliary switch is closed, so that there is no control voltage at the energy store.

The switching device according to the invention according to FIG. 1 can also be used very advantageously in air-insulated switchgear. In such cases, the housing is designed and sealed so that corrosive influences from the environment cannot penetrate into the interior of the switching device. The length of the insulating tube 6 is also adapted to the harsher environmental influences.

In some applications, it is desirable not to trigger the device immediately in the event of a fault. In the conventional switchgear, adjustable overcurrent protection relays are used, with which the response time of the release can be changed. However, such relays have the major disadvantage that they have to be checked at certain time intervals. This is only permitted if the branch is disconnected.

Longer tripping times can be achieved with the switching device according to the invention according to a further feature by adding a capacitance 28, preferably parallel to the ring coil 5a of the magnetic release 5 according to FIG. According to FIG. 5, the capacitance can be designed as a cylindrical capacitor 28 a. The cylindrical capacitor 28 a is advantageously arranged in a gap between the secondary winding 4 b of the current transformer 4 and the metal tube 7 of the housing. The two pads are connected according to the circuit diagram of Figure 4 with the outputs of the secondary winding 4 b and the toroidal coil 5a. According to another feature of the invention, a plate capacitor 28b can also be used as a capacitance for influencing the switch-off time for the switching device. This plate capacitor 28 can advantageously be arranged between the current transformer 4 and the magnetic release 5. Here, too, the connection is made according to the circuit diagram in FIG. 4. In all cases, openings b 42 are provided in the ferromagnetic body 5 b, through which the electrical connections to the capacitors or to the secondary coil 4 a of the current transformer 4 are made.

Claims (27)

1st Switching device for interrupting fault currents, preferably for transformer feeders in medium-voltage switchgear

a switch suitable for carrying out repeated interruptions and operated by an energy store with at least one switch-off spring, and a tripping device which becomes effective when a fault current occurs,

characterized in that for each phase a housing provided with two connecting pieces (2, 3) is provided, in which

- a vacuum interrupter (1) with a fixed and a movable switching contact (1a, 1b), - A current transformer (4) and - The opening spring (9) with a by a magnetic release (5) detachable latch (10) are housed, and - That the housing has means for indicating the position of the movable switching contact (1b) and for reclosing the vacuum interrupter (1) after a power interruption. 2. Switching device for interrupting fault currents according to claim 1, characterized in that the housing in one the first space contains the vacuum interrupter (1) and means for connecting its stationary switch contact (1a) to the first connection (2), and that the movable switch contact (1b) with its shaft or possibly with an extension (25) is one Partition (8) penetrates to a second room in which the remaining resources (4,5,9,10) and a sliding contact connection (24) between the shaft of the movable contact (1b) or possibly the extension (25) and the second connector (3) are installed. 3. Switching device for interrupting fault currents according to claim 2, characterized in that the housing has a cylindrical shape in which the vacuum interrupter (1) and the remaining resources (4.5,9,10) are installed in a coaxial arrangement that a at least in part from an insulating tube (6) closed on the end face with the first connecting piece (2), the outer surface of the first space, and that a metal tube (7) closed off from the first space by the partition (8), in the end face of which second connector (3) is used, which forms the outer surface of the second room. 4. Switching device for interrupting fault currents according to claim 2 or 3, characterized in that in the second space of the housing starting from the partition (8) from a shaft of the movable switching contact (1b) or possibly its extension (25) surrounding toroid (4a) and a secondary winding (4b) existing current transformer (4) and consisting of a toroidal coil (5a), a ferromagnetic body (5b) enclosing this except for an air gap (26) for a displaceable magnet armature (5c) ) and the latch (10) of the opening spring (9) are installed. 5. Switching device for interrupting fault currents after Claim 4, characterized in that the current transformer (4) and the magnetic release (5) have an annular gap with respect to the shaft of the movable switching contact (1b) or its extension (25), if necessary, for receiving the partition (8) and a pressure piece (10b) of the latch (10) supporting switch-off spring (9). 6. Switching device for interrupting fault currents according to claim 5, characterized in that in the switched-on position of the vacuum interrupter (1) the pressure piece (10b) acts on an inclined surface on the circumferentially arranged clamping body (10a) so that the latter with support an axial component on a support plate (10c) and a radial component on the inside of the magnet armature (5c). 7. Switching device for interrupting fault currents according to claim 6, characterized in that the ring coil (5a) acted upon by a fault current pulls the magnet armature (5c) into the air gap (26), whereupon the clamping body (10a) under the action of the radial component move the switch-off spring (9) to the outside while releasing the lock by the pressure piece (10b) and release the switch-off movement of the movable contact (1b). 8. Switching device for interrupting fault currents according to one of the claims 4 to 7, characterized in that the magnet armature (5c) has an inclined end face (29) which, after tensioning the opening spring (9) under the action of a return spring (14) Clamping body (10a) leads into its locked position and holds it there. 9. Switching device for interrupting fault currents according to claim 2 or one of the following, characterized in that that in the shaft of the movable switching contact (1b) or possibly in its extension (25) a pin (15) is attached, on which the pressure piece (10b) the force of the opening spring (9) during the opening of the vacuum interrupter (1) transmits. 10. Switching device for interrupting fault currents according to claim 9 or one of the preceding, characterized in that between a shoulder (21) on the shaft of the movable switching contact (1b) and the pressure piece (10b), optionally with the interposition of a tube (11), a contact force spring (12) is provided, which is supported on the pin (15) when the vacuum interrupter (1) is switched off. 12. Switching device for interrupting fault currents according to claim 11, characterized in that the switch-off spring (9) via a screw spindle (18) mounted in the base of the second connecting piece (3) can be tensioned. 13. Switching device for interrupting fault currents according to claim 12, characterized in that the screw spindle (18) via an insulating shaft (19) can be actuated from outside an encapsulation (31) of the switchgear. 14. Switching device for interrupting fault currents according to one of the claims 11 to 13, characterized in that a motor drive (34) for tensioning the switch-off spring (9) and for switching on the vacuum switching chamber (1) is provided, which has means for automatic operation after elimination of a malfunction which includes the automatic return of the screw spindle (18) after the switch-on movement has been carried out. 15. Switching device for interrupting fault currents according to claim 1 or one of the subsequent claims, characterized in that the connecting pieces (2, 3) adapters (2a, 3a) to accommodate the switching device in clamping contacts (35) provided for high-performance fuses. 16. Switching device for interrupting fault currents according to claim 2, characterized in that a sliding contact (24) is provided as a displaceable contact connection, the elements of which are guided on the connecting piece (3). 17. Switching device for interrupting fault currents according to claim 1 or one of the subsequent claims, characterized in that between the first connecting piece (2) and the fixed switching contact (1a) a coil-shaped conductor for generating an axial magnetic field for the switching path of the vacuum interrupter ( 1) is provided. 18. Switching device for interrupting fault currents according to claim 17, characterized in that the conductor (23) is spirally wound and with its outer end with the first connector (2) and with its inner end with the stationary switch contact (1a) is conductively connected . 19. Switching device for interrupting fault currents according to claim 18, characterized in that the shaft of the fixed switching contact (1a) is held by means of a screw connection (27) mounted in an insulated manner in the first connecting piece (2). 20. Switching device for interrupting fault currents according to claim 2 or 3, characterized in that the shaft of the fixed switching contact (1a) is connected to the inside of the first connector (2) by means of a screw connection. 21. Switching device for interrupting fault currents according to one of the claims 1 to 4, characterized in that the secondary winding (4b) of the current transformer (4) and the ring coil (5a) of the magnetic release (5) are connected in series. 22. Switching device for interrupting fault currents according to one of the claims 1 to 4, characterized in that in series with the secondary winding (4b) of the current transformer, the toroidal coil (5a) of the magnetic release and in parallel with the latter preferably a capacitor (28) are connected. 23. Switching device for interrupting fault currents according to claim 22, characterized in that the capacitance is designed as a wound capacitor (28a) and is arranged around the winding (4b) of the current transformer (4). 24. Switching device for interrupting fault currents according to claim 22, characterized in that the capacitance is designed as a plate capacitor (28b) and is arranged between the current transformer (4) and the magnetic release (5). 25. Switching device for interrupting fault currents according to claim 1 or one of the subsequent claims, characterized by means with which the disconnection movement of the movable switching contact (1b) or its extension (25) for disconnecting an assigned disconnector or load switch (32a) can be transmitted. 26. Switching device for interrupting fault currents according to claim 26, characterized in that the end protruding from the housing (25a) acts via a linkage (36) on the energy store (38) of the disconnector or load switch (32a) and its separation after a Residual current interruption caused by the vacuum interrupter (1). 27. Switching device for interrupting fault currents according to claim 25, characterized in that from the Ends protruding from the housing (25a) act on auxiliary contacts (39) which are preferably arranged outside the encapsulation (31) and can be used to apply a shunt release in the energy store (38) of the disconnector or load switch (32a) after a fault current interruption. 28. Switching device for interrupting fault currents according to claim 27, characterized in that the switching devices (33) cooperate with two auxiliary contacts (39), and that an auxiliary contact of two different phases with each other and with the shunt release of the energy store (38) in series are switched.

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