EP0145994A2 - Medium voltage switching device - Google Patents

Abstract

An electrical, medium voltage, switching mechanism which includes a casing having an insulating material filling. In the casing, between a cable connection and a bus bar, a change-over switch, which can alternately switch between a phase contact and a ground contact, follows a load disconnector which is in the form of a vacuum switching tube. An axially displaceable shaft is provided which is displaceable relative to the load disconnector and is rotatable relative to the change-over switch. The bus bar passes through an insulator at right angles thereto. The associated through passage in the insulator is widened into a slot, the length of which permits the switching movements of the load disconnector. The insulator is divided into an insulator core and an insulator casing which is rotatably mounted on the insulator core. In the region of the insulator casing, the through passage is further widened into two sector windows which have an angular aperture which permits the switching movements of the rotary contact of the change-over switch. As a result, the switching mechanism has a structural form which at high operational reliability requires little space, is economical to manufacture, and can be serviced in a time saving manner.

Description

The invention relates to an electrical medium-voltage switching device, in which, in an encapsulation with a gaseous or liquid insulating agent filling between a cable connection and a busbar, a vacuum contact tube with a stationary contact piece and with an axially movable mating contact piece connected to an actuating device via an insulating body is formed Switch disconnector is arranged downstream of a switch that can be alternately switched between a phase contact and an earth contact.

Such a switching device does not require a separate, pure earthing switch and incorporates the load-break switch into the earthing process, in that after the switch has been switched from the phase contact to the earth contact, the two contact pieces of the load-break switch switch are brought together again. A lock in the actuating device ensures that the changeover switch can only be actuated when the switch disconnector is open. The changeover switch is thus partly a phase isolating switch that disconnects from the load, and partly an earthing switch that also disconnects from the load in a figurative sense. The use of a vacuum interrupter allows a particularly large number of high-energy switching cycles. Including the encapsulation and the filling of the insulating agent, the switching device is maintenance-free for a long time and offers a high level of safety even in a damp, dusty or otherwise aggressive environment.

From DE-PS 28 18 905 in connection with an electrical medium-voltage control panel, in which each of the entire cable connection is arranged in an air-insulated base frame common to all phases, is already the stringing together of a vacuum interrupter and a conventional disconnector between a cable connection and a busbar known in an insulating gas-filled metal encapsulation. The vacuum interrupter is centered by an insulating plate at the lower end of a tubular container, while the isolating switch is in a second container containing the busbar. Despite the objective of being able to maintain the control panel in a cost-effective manner and to keep the insulating gas volume of the control panel encapsulation small, the removal of the two switches from the insulation gas-filled encapsulation and vice versa, the installation, can only be accomplished in stages and with a greater expenditure of time, and require the two side entries the switch drives require a proportionately large amount of space in addition to a complicated container shape.

The invention has for its object to provide for a medium-voltage electrical switching device of the type mentioned in a space-saving design that requires little space, is inexpensive to manufacture and time-saving to maintain.

This object is achieved in that for the switch disconnector and the switch an axially displaceable shaft with the switch disconnector assigned displaceability and the switch associated rotatability is provided as a common actuating element.

This means that container parts that protrude transversely from a tubular encapsulation can be avoided and both switches inserted into the encapsulation and pulled out of it again for maintenance purposes. The insulation filling can be supplemented by a solid insulation that prevents so-called thread formation and thus spray discharges or breakdowns, which has a coaxial position with the outer encapsulation and the two switches and its protective function is not impaired by local interruptions. In addition, a shaft to be sealed is avoided with the shaft common to the two switches. However, the advantages achieved by the invention are in particular that the actuating devices of the load-break switch and the changeover switch can be spatially closely combined, which leads to considerable further space savings.

• Fig. 1 einen Längsschnitt durch die beschriebene Schaltvorrichtung,
• Fig. 2 einen Schnitt gemäß der Linie A-B in Fig. 1 und
• Fig. 3 einen Schnitt gemäß der Linie C-D in Fig. 1.

A particularly preferred embodiment on the basis of the embodiments of the invention specified in the subclaims Example of the invention is shown in the drawing and will be described in more detail below. It shows

• 1 shows a longitudinal section through the switching device described,
• Fig. 2 shows a section along the line AB in Fig. 1 and
• 3 shows a section along line CD in FIG. 1.

The encapsulation 10 of the switching device shown in the drawing mainly consists of a circular cylindrical tube with two branches coaxially enclosing a section of the busbar 11 near one end of the circular cylindrical tube. In this respect, it is preferably welded together from sheet steel parts and thus has good electrical conductivity, as a result of which it can be kept touch-proof at earth potential anywhere. The insulating oil filling 12 of the switching device provided as voltage protection passes into the area of the busbar 11 without a partition. The voltage protection is supplemented by a cylinder tube 13 made of electrically insulating material, which encloses all active parts of the switching device with an intermediate space to the encapsulation 10 and contributes to fixing them in position.

To complete the encapsulation 10, a circular cover 15 is flanged to one end of the circular cylindrical tube with the interposition of a sealing ring 14, through which the axially displaceable shaft 16 is passed coaxially, and to the other end This circular cylindrical tube is used to adapt to different cable connections, an interchangeable adapter ring 17, to which, with the interposition of a sealing ring 18, the insulating jacket 19 of a conductor leadthrough 20 projecting conically into the encapsulation 10 is flanged. The cover 15 and the adapter ring 17 each have an annular groove for receiving one end of the inner cylinder tube 13.

While the stationary contact piece 21 of the load break switch 21, 22 is fastened coaxially to the inner end of the conductor bushing 20, the axially movable mating contact piece 22 of the load break switch 21, 22 is coaxial to the insulating body core 23, which can be displaced axially via the shaft 16, into an insulating body core 23 and an insulating body jacket 24 divided insulating body 23,24 attached. Except for the respective connection end, the contact piece 21 and the counter contact piece 22 are located in a circular cylindrical vacuum vessel 25.

The rotary contact 28 of the switch 26, 27, 28, which can be alternately switched between the phase contact 26 and the earth contact 27, is attached to the insulating body 23, 24 inserted between the shaft 16 and the axially movable mating contact piece 22 of the load-break switch 21, 22. Thus, the two successive switches 21, 22 and 26, 27, 28 not only have a common actuating element in the form of the axially displaceable shaft 16, but also a common protective element which keeps the electrical voltage from the actuating devices. It follows that not only the actuators of switch disconnector 21, 22 and changeover switch 26, 27, 28 can be spatially closely merged, but also the two switches themselves, which takes up space the switching device is again considerably reduced and the removal and installation of the two switches is further simplified. In order to achieve decoupling of the different switching movements despite the physical combination of peripheral parts of the load break switch 21, 22 and the changeover switch 26, 27, 28 and to advance the location of this decoupling as far as possible, the rotary contact 28 must be moved from the axial displacement movement of the shaft 16 by a except for the axially parallel guide provided for it on the insulating body 23, 24 and connected via a flexible conductor or a sliding contact to the axially movable counter-contact piece 22 of the load-break switch 21, 22.

The shaft 16 is preferably guided far from the cable connection 19, 20 on the side of the busbar 11 through the encapsulation 10 in the sealing seat. This makes it possible to use the space required for the busbar 11 within the encapsulation 10 to a greater extent for the accommodation of switch parts. In accordance with the drawing, this is realized in such a way that the busbar 11 is passed through the insulating body 23, 24 at right angles, the through opening provided in the insulating body 23, 24 for the busbar 11 to the length of the axial switching movements of the mating contact piece 22 of the switch disconnector 21,22 permitting elongated hole 29 is expanded, the insulating body 23, 24 is divided into an insulating body core 23 which is rotationally symmetrical with respect to its axis and an insulating body jacket 24 which is rotatably mounted on the insulating body core 23, and the through opening provided in the insulating body 23, 24 for the busbar 11 in the region of Isolierkörpermantels 24 to two offset by 180 degrees in their Opening angle, the switching movements of the rotary contact 28 permitting sector windows 30 is further expanded.

In all of this, the phase contact 26 of the changeover switch 26, 27, 28 consists of a guide finger, which is guided together with the busbar 11 through the insulating body 23, 24, is attached lengthwise to the busbar 11 with a wide contact surface, and has a contact finger protruding at both ends at both ends 31 equipped molded bodies to give it a particularly firm hold and to be able to transfer stronger electric currents. The phase contact 26 is given a secondary function which simplifies the construction and assembly of the switching device, in that the two end faces of the molded body forming the phase contact 26 act as a support for the changeover switch 26, 27, 28 and the load break switch 21, 22 with an intermediate space from that of electrically conductive Material existing encapsulation 10 together enclosing cylinder tube 13 are used made of electrically insulating material. On each of the two supports there is a fixing screw 32 connecting the cylinder tube 13 to the phase contact 26, the head of which can be reached via the respective branch created for the busbar 11 in the encapsulation 10, is countersunk into the cylinder tube 13 and usually by one on the cylinder tube 13 displaceable insulating sleeve 33 is covered. The connection of the phase contact 26 to the busbar 11 is provided by two cylinder head screws 34 which, parallel to the longitudinal axis of the switching device, reach through the busbar 11 in the area between the cylinder tube 13 and the insulating jacket 24 and can be reached from the side / associated with the axially displaceable shaft 16.

In adaptation to the high-current version of the phase contact 26 and to make a contribution to a high level of operational safety, a small space requirement, an inexpensive production and a time-saving maintenance, the earth contact 27 of the switch 26, 27, 28 consists of two 90 degree degrees to the contact fingers 31 des Phase contact 26 offset, outside the insulating body jacket 24 parallel to its axis of rotation and merged on the shaft 16 flat rails. Characterized in that the rotary contact 28 of the switch 26,27,28 has two ends arranged for resilient broadside inclusion of the contact fingers 31 of the phase contact 26 or the correspondingly shaped free ends of the earth contact 27 with the longitudinal sectional view of a two-pronged fork and the rotary contact ends 35 narrowly between two are loosely guided by the insulator body jacket 24, the high current suitability of the rotary contact 28 is further improved and the rotary contact 28 is excluded from the axial switching movements of the insulated body 23, 24 inserted between the mating contact piece 22 of the load-break switch 21, 22 and the shaft 16 in a particularly simple manner .

The axially displaceable shaft 16, which is provided as a common actuating element for the load break switch 21, 22 and the changeover switch 26, 27, 28, is rotatably mounted with an end collar 37 without axial play with respect to the insulating body core 23 at its front end. Laterally next to the end collar 37, the shaft 16 is provided with radial arms 38, the outer end of which is attached to the end face of the insulating body jacket 24. The cover 15, which completes the encapsulation 10, has an outwardly projecting central insert 39, which gives the axially displaceable shaft 16 better guidance and more than one wel seal offers 40 space. Outside the encapsulation 10, the shaft 16 ends with a drive disk 41 fastened to it and partially enclosing the insert 39. For the connection of the actuating device of the load-break switch 21, 22 (not shown in the drawing), a coupling groove 42 is provided in the periphery of the drive disk 41 provided and for the connection of the actuating device of the switch 26, 27, 28, also not shown in the drawing, attached to the inner end face of the drive pulley 41, a pivot lever 43. The installation of the electrical medium-voltage switching device described, for example in a transformer station or distribution station, is ultimately carried out in such a way that a busbar 11 is pushed through the switching device and screwed into it and the encapsulation 10 is completed by flanging pipe pieces enclosing the busbar 11 coaxially.

Claims (9)

1. Electrical medium-voltage switching device, in the encapsulation with a gaseous or liquid insulating agent filling between a cable connection and a busbar as a vacuum interrupter with a stationary contact piece and with an axially movable and via an insulating body connected to an actuating device, a switch disconnector alternately between a phase contact and an earth contact switchable switch is arranged downstream, characterized in that for the load-break switch (21,22) and the switch (26,27,28) an axially displaceable shaft (16) with the load-break switch assigned displaceability and the switch-associated rotation as common actuator is provided. 2. Switching device according to claim 1, characterized in that the alternately between the phase contact (26) and the earth contact (27) switchable rotary contact (28) of the switch (26,27,28) on the between the shaft (16) and the axially Movable mating contact piece (22) of the load-break switch (21, 22) inserted insulating body (23, 24) is attached. 3. Switching device according to claim 2, characterized in that the rotary contact (28) is exempted from the axial sliding movement of the shaft (16) by an axially parallel guide provided for it on the insulating body (23, 24) and via a flexible conductor or a sliding contact the axially movable counter-contact piece (22) of the load-break switch (21, 22) is connected. 4. Switching device according to claim 3, characterized in that the shaft (16) far from the cable connection (19, 20) on the side of the busbar (11) through the encapsulation (10) in the sealing seat. 5. Switching device according to claim 4, characterized in that the busbar (11) through the insulating body (23,24) is passed at right angles crossing, the through opening provided in the insulating body (23,24) for the busbar (11) to a length the axial switching movements of the mating contact piece (22) of the load-break switch (21, 22) allowing the elongated hole (29) to be expanded, the insulating body (23, 24) into an insulating body core (23) that is rotationally symmetrical to its axis and one that is rotatably mounted on the insulating body core (23) Insulating body jacket (24) is divided and the through opening provided in the insulating body (23, 24) for the busbar (11) in the area of the insulating body jacket (24) is offset by two angular degrees from one another in their opening angle, which allows the switching movements of the rotary contact (28) to allow the switching movements of the rotary contact (28) 30) is expanded again. 6. Switching device according to claim 5, characterized in that the phase contact (26) of the switch (26,27,28) from a together with the busbar (11) through the insulating body (23,24), the length with a wide contact surface molded body attached to the busbar (11) and equipped at both ends with a contact finger (31) protruding at right angles. 7. Switching device according to claim 6, characterized in that the two end faces of the phase contact (26) forming the molded body as a support for the changeover switch (26, 27, 28) and the load break switch (21, 22) with an intermediate space from which it is made electrically Conductive encapsulation (10) together enclosing cylinder tube (13) are used made of electrically insulating material. 8. Switching device according to claim 6 or 7, characterized in that the earth contact (27) of the switch (26,27,28) from two by 90 degrees to the contact fingers (31) of the phase contact (26) offset outside the insulating body jacket (24th ) parallel to its axis of rotation and on the shaft (16) merged flat rails. 9. Switching device according to claim 8, characterized in that the rotary contact (28) of the switch (26,27,28) two for resilient broadside inclusion of the contact fingers (31) of the phase contact (26) or the correspondingly shaped free ends of the earth contact (27th ) has arranged ends with the longitudinal sectional view of a two-pronged fork and the rotary contact ends (35) on the narrow side are loosely guided between two wings (36) rising from the insulating body jacket (24).

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