DE10022185A1 - Trigger for an enclosed switchgear - Google Patents

Abstract

The invention relates to a trigger for an encapsulated switchgear, in particular a gas-insulated medium-voltage switchgear, consisting of one or more switch springs in a common gas filling, essentially with switch disconnectors and / or circuit breakers, earthing switches, drive elements, busbars and connected lines. In order to guarantee quick and safe grounding of the system or triggering of the higher-level protection systems in the event of an arcing fault, the trip unit has a housing which is arranged on the encapsulation of the switchgear and has a cylinder section in which an actuating piston is mounted, with the inside of the Switchgear and the cylinder section there is a fluid connection.

Description

The invention relates to a trigger for an encapsulated switchgear, in particular a gas-insulated medium-voltage switchgear from one or more switch springs in a common gas filling essentially with switch disconnectors and / or circuit breakers, Er voltage switches, drive elements, busbars and connected its lines.

A triggering device of the generic type is known from DE 36 06 770 C2 known. Then in the event of an arcing fault in a switchgear the pressure generated by the arc is used to create a scarf tung, d. H. Earthing the system. According to the known Teaching is a flexible section provided in the Störlichtbo if necessary, acts on a linkage, which in turn is used as a spring mechanism tensioned energy store is triggered, which in turn all in the system located earth actuated, regardless of where the Arc in the switchgear in any case interrupt safely.

DE 196 01 639 A1 also describes a triggering device for Switchgear described in which the pressure in of the switchgear and in the case of an impermissibly high value by a gas generator, as is known from airbag devices, a latch is triggered and grounding is reached.

While the last-mentioned version of a trigger device very much is complex, the solution explained first has proven its worth, although there is a quasi indirect release.

It is therefore an object of the present invention to provide a trigger for Generic systems to create a simple and com compact structure and a short and direct actuation of the Force storage enables and / or the triggering of a higher-level Protection system.

This object is achieved by
a housing preferably arranged on the encapsulation of the switchgear,
an actuating piston receiving cylinder section in the housing and
a fluidic connection between the interior of the switchgear and the cylinder section
solved.

Based on this combination of features of a piston-cylinder system stems for direct actuation of the energy store and / or release a higher-level protection system using a fluidic Connection results in a wide range of applications with high Si security standard.

According to a first preferred embodiment it is provided that the actuator tion piston acts on a trigger element when it is displaced with an energy storage drive and / or a tripping / signaling contact in Connection is established. Between the actuating piston and the power spit  cherantrieb and / or the trigger / signaling contact is preferably only one only trigger element arranged in the form of a trigger lever.

A particularly simple and therefore also economically producible off leadership is achieved when the fluidic connection by an im essential cylindrical part with a longitudinal bore and at least a transverse bore intersecting the longitudinal bore or at least a slot intersecting the longitudinal bore is created. Here the cylindrical part is arranged in a bore in the housing, the communicates with an opening of the encapsulation. This is an advantage drische part a screw with a hollow or blind hole, the con is arranged centrally to the opening.

The trigger can then be advantageously on the Schaltan be attached if there is a Threaded bush is attached, in which the screw is inserted; the Ge The wind socket is preferably concentrically attached to the encapsulation welds. For safe operation, according to training, between Threaded bushing and housing arranged a seal; can also the trigger must be welded directly to the switchgear enclosure.

Securing the position of the piston in the cylinder is essential interpretation, especially taking into account the fact that the trigger is the system overpressure and operational tempera must be able to compensate for short cycles without being triggered Act. It is therefore provided that an elastic on the actuating piston Element, in particular a spring element that attacks the actuation holds the piston in a rest position. The spring element can be a ring spring or a suitable double leaf spring. The spring can be in one  Intervene in the rod of the actuating piston and in the Ge housing cover of the release device be held.

A corresponding compensation effect has another Feature of the invention one from the piston rod end in the event of a malfunction penetrating metal or plastic film that only when a yields or breaks predetermined pressure levels.

Can between the cylinder section and the actuating piston a seal can also be arranged so that in the event of an arcing fault it is ensured that the pressure energy entirely for the actuation of the Kol can also be used.

A connection for a measuring instrument or a signal can be connected to the trigger be arranged switch.

The trigger housing is preferably made of plastic or aluminum nium. The actuating piston is preferably also made of plastic or of a similarly light material.

In the drawing, an embodiment of the invention is shown. Show it:

Fig. 1 shows a schematic section of a medium-voltage switching system with trigger and force accumulator,

Fig. 2 shows a section through the trigger.

In Fig. 1, 1 denotes a gas-insulated, encapsulated medium-voltage switching system, of which only part of the encapsulation 5 can be seen, to which the trigger 2 is attached.

In the event of a pressure increase in the system 1 as a result of an arcing fault, an actuating piston, to be described in more detail, acts with its rod 13 on the release lever 3 , which is connected to the energy accumulator 4 . By actuating the energy accumulator 4 in the event of an arcing fault, earthing switches (not shown ) are triggered in the switchgear 1 . Further details can be found in DE 36 06 770 C2.

Details of the triggering device 2 are shown in FIG. 2. The device 2 is connected to switchgear 1 , of which only a wall part of the encapsulation 5 can be seen in the figure. The encapsulation 5 has an opening 6 , in which a threaded bushing 7 is inserted and welded to the encapsulation 5 in a gas-tight manner.

The trigger 2 is screwed to the encapsulation 5 of the switchgear assembly 1 by means of a screw 8 via the threaded bushing 7 .

The trigger 2 has a housing 9 which, as shown in FIG. 2 in the upper loading region, is designed as a cylinder section 11 which receives an actuating piston 12 with a piston rod 13 which projects through a housing cover 14 of the trigger 2 . In the event of an arcing fault, the end 15 of the piston rod 13 acts on the release lever 3 shown in FIG. 1.

In the area shown at the bottom in FIG. 2, the housing 9 is cuboid with a continuous cylinder bore 16 , but here the cylinder axis is perpendicular to the axis of the cylinder section 11 . The bore 16 is penetrated by the screw 8 , which is provided with a blind or hollow bore 17 .

The screw 8 has in addition to the bore 17 , which extends in the longitudinal direction of the screw, in its wall or slots 18 . As can be seen from Fig. 2, this results in a fluidic connection 19 between the interior of the switchgear 1 and the cylinder section 11 , that is, a connection that enables the pressure exchange.

The pressure that arises inside the switchgear 1 in the event of an arc acts via the hollow bore 17 and the transverse bores / slots 18 on the bottom of the actuating piston 12 , which moves in the direction of the arrow as a result of the increasing pressure and with its piston end 15 on the release lever 3 after overcoming the compensation counterpressure presses, which operates the energy accumulator 4 .

So that this actually takes place only in the event of an arcing fault, the piston rod 13 has a conically shaped recess 21 into which an elastic element in the form of an annular spring 22 engages. As can be seen from Fig. 2, a certain minimum pressure is required to move the piston rod 13 against the pressure of the spring 22 in the direction of the arrow. The spring force is selected in the present case so that an overpressure between 500 mbar and 1 bar must be present inside the switchgear 1 in order to actuate the piston 12 .

For the gas-tight design, a seal 23 or 24 is arranged between the threaded bushing 7 and the housing 9 and between the cylinder section 11 and the piston 12 .

The trigger in the illustrated embodiment also has a connection 25 for a manometer 26 , which in the present case consists of a threaded bore in the hexagon head of the screw 8 extending to the blind bore 17 . The manometer 26 or other measuring and display instruments can be screwed into this threaded bore 25 .

The trigger described is characterized in particular by the fact that it can be arranged in the immediate vicinity of the energy accumulator and only a single transmission element (release lever 3 ) is required for actuation.

Claims (24)

1.Trigger ( 2 ) for an encapsulated switchgear, in particular a gas-insulated medium-voltage switchgear ( 1 ), consisting of one or more switch springs in a common gas filling, essentially with switch disconnectors and / or circuit breakers, earthing switches, drive elements, busbars and connected Cables,
marked by
a housing ( 9 ) preferably arranged in or on the encapsulation ( 5 ) of the switchgear ( 1 ),
an actuating piston ( 12 ) receiving the cylinder section ( 11 ) in the housing ( 9 ) and
a fluidic connection ( 19 ) between the interior of the switchgear ( 1 ) and the cylinder section ( 11 ). 2. Trigger according to claim 1, characterized in that the piston ( 12 ) actuates a trigger element ( 3 ) connected to an energy accumulator ( 4 ) during its displacement. 3. Trigger according to claim 2, characterized in that the trigger element ( 3 ) consists of only one lever. 4. Trigger according to claim 1, characterized in that the piston ( 12 ) causes a triggering of the superordinate protection system when it is displaced. 5. Trigger according to one of claims 1 to 4, characterized in that the fluidic connection ( 19 ) by a wesentli chen cylindrical part ( 8 ) with a longitudinal hollow bore ( 17 ) and at least one transverse bore intersecting the longitudinal bore ( 18 ) or at least one slot intersecting the longitudinal bore is created. 6. Trigger according to claim 5, characterized in that the longitudinal axis of the cylinder section ( 11 ) is perpendicular to that of the cylin drical part ( 8 ). 7. Trigger according to claim 5 or 6, characterized in that the cylindrical part ( 8 ) in a bore ( 16 ) in the housing ( 9 ) is arranged, which communicates with an opening ( 6 ) of the encapsulation ( 5 ). 8. Trigger according to one of claims 5 to 7, characterized in that the cylindrical part ( 8 ) is a screw with a blind or hollow bore ( 17 ) which is arranged concentrically with the opening ( 6 ). 9. Trigger according to claim 8, characterized in that the housing ( 9 ) by means of the screw ( 8 ) which is screwed into a threaded bushing ( 7 ) fastened to the encapsulation ( 5 ) is fastened to the switching system ( 1 ). 10. Trigger according to claim 9, characterized in that the threaded bush ( 7 ) is welded concentrically to the opening ( 6 ) on the encapsulation ( 5 ). 11. Trigger according to one of claims 7 to 10, characterized in that the housing ( 9 ) is welded concentrically to the opening ( 6 ) on the encapsulation ( 5 ). 12. Trigger according to one of claims 9 to 11, characterized in that between the threaded bush ( 7 ) and the housing ( 9 ) a seal ( 23 ) is arranged. 13. Trigger according to one of claims 1 to 12, characterized by an elastic element ( 22 ), in particular a spring element on the actuating piston ( 12 ), for compensation of the system pressure and / or temperature fluctuations. 14. Trigger according to claim 13, characterized in that the spring element ( 22 ) is an annular spring. 15. Trigger according to claim 14, characterized in that the annular spring ( 22 ) engages in the piston rest position in a recess ( 21 ) in the rod ( 13 ) of the actuating piston ( 12 ) and in the Ge housing cover ( 14 ) of the trigger ( 2 ) held is. 16. Trigger according to claim 13, characterized by at least a leaf spring as a spring element. 17. A trigger according to claim 13, characterized by a of the piston rod ( 13 ) when leaving the rest position to be pierced film or the like. 18. Trigger according to one of claims 1 to 17, characterized in that between the cylinder portion ( 11 ) and the actuating piston ( 12 ) a seal ( 24 ) is arranged. 19. Trigger according to one of claims 1 to 18, characterized by a connection ( 25 ) for a measuring instrument ( 26 ), in particular for a manometer on the housing ( 9 ). 20. Trigger according to one of claims 1 to 19, characterized in that the housing ( 9 ) consists of plastic. 21. Trigger according to one of claims 1 to 19, characterized in that the housing ( 9 ) consists of light metal, in particular aluminum. 22. Trigger according to one of claims 1 to 21, characterized in that the actuating piston ( 12 ) consists of plastic. 23. Trigger according to one of claims 1 to 21, characterized in that the actuating piston ( 12 ) is made of light metal. 24. Trigger according to one of claims 13 to 23, characterized by a with the elastic element ( 22 ) cooperating conical tip of the piston rod ( 13 ).