DE4210545A1 - Breaker switch for metal-encapsulated HV switch appts. - has pair of cooperating movable and stationary contact pieces within switch encapsulation, each having pre-ignition contact pin - Google Patents

Abstract

The breaker switch uses a pair of cooperating contact pieces lying along a common axis (4) within the switch encapsulation, each having a pre-ignition contact pin (14, 16). The contact pin of the stationary contact piece is enclosed by a coaxial stationary contact (15), that of the movable contact piece by a mobile contact (10) forming a continuous current path with the stationary contact (15) in the closed switch position. The mobile contact comprises a contact sleeve (13) providing a sliding mounting for the pre-ignition contact pin (14) and receiving the pre-ignition current transferred via the latter. A coil spring (18) pref. acts between the pre-ignition contact pin and an internal shoulder (19) of the contact sleeve. ADVANTAGE - Reduced axial length without breakdown of insulation path upon separation of contacts.

Description

TECHNICAL AREA

The invention is based on a disconnector for a metal-encapsulated gas-insulated high-voltage system with two in the metal gas-filled encapsulation arranged and along an axis with each other Contactable or separable contact pieces each with a pin-shaped, axially extended Pre-ignition contact, which as one of both contacts Trailing contact is formed, and with a Pre-ignition contact of a fixed two contact pieces coaxial surrounding fixed contact and one on one movable contact provided for both contact pieces, which in the switch-on position with the fixed contact Continuous current path forms.

STATE OF THE ART

The invention relates to a prior art, as it results for example from DE-C2-32 37 146. In this patent publication is a circuit breaker for a metal-encapsulated gas-insulated high-voltage system with  two in a grounded, gas-insulated metal enclosure arranged, contactable with each other or from each other separable contact pieces described, one of them lengthways one axis is movably guided. When you turn this on Disconnectors can vary depending on those in the high voltage system prevailing potential relationships between the Contact pieces pre-ignition occur. To avoid that these pre-ignitions during the switching process are not too Cross-cuts and thus short-circuits with the grounded encapsulation, it is ensured that the pre-ignition that may occur is centered axially are. This is achieved on the one hand by using the as Movable contact piece designed up to a pin Intermediate position a shield is moved. To the others this is also achieved by the fact that on fixed both contact pieces as a pre-ignition electrode acting, pin-shaped follow-up contact is provided.

This circuit breaker has a comparatively large one axial expansion. This is due to the fact that the trailing contact additional construction elements in the fixed switching piece are introduced, which in have a considerable extent in the axial direction and high voltage must be shielded. this leads to a not inconsiderable increase in the already one largely due to the isolation distance of the open Isolation distance determined disconnector geometry in axial Direction.

SUMMARY OF THE INVENTION

The invention as defined in claim 1 the task is based on a disconnector for a metal-encapsulated gas-insulated high-voltage system from Specify the type mentioned, in spite of less Dimensions undesirable in the axial direction Cross-cuts are almost completely suppressed.

The invention takes advantage of the knowledge that in movable contact piece due to its running contact when switching on or off executed switching strokes in Difference to the fixed contact in axial In the direction of sufficient space for installing the overrun contact is available. This is achieved by installing the Follow-up contact in the running contact Disconnector geometry compared to a switch without Overrun contact not changed compared to a switch with one arranged in the fixed contact Trailing contact, however, considerably in the axial direction shortened. Through suitable further training of the Running contact integrating running contact can Disconnect switch geometry in the axial direction while maintaining the great resistance to cross-cuts can be shortened even further.

Embodiments of the invention and the achievable therewith Advantages are explained in more detail below with reference to drawings explained.  

BRIEF DESCRIPTION OF THE DRAWINGS

In the drawings, two embodiments of the The invention is shown schematically, namely:

Fig. 1 is a plan view of an axial section through the housing and contact assembly of a first embodiment of the disconnector according to the invention in which the circuit breaker is in the left half in the on position and in the right half in the off position,

Fig. 2 in an enlarged view the contact arrangement of the circuit breaker according to Fig. 1, and

Fig. 3 is a plan view of an axially guided section through a contact arrangement of a second embodiment of the circuit breaker according to the invention, in which according to the embodiment of FIG. 1, the circuit breaker in the left half in the on and in the right half in the off position located.

WAYS OF CARRYING OUT THE INVENTION

In all figures, the same reference numerals also refer to parts having the same effect. The isolating switch shown in FIG. 1 has a housing designed as a grounded metal encapsulation 1 and filled with an insulating gas, such as SF ₆ , of a few bar pressure. The metal encapsulation 1 contains three openings (not designated), two of which are sealed gas-tight with one of two partition insulators 2 , 3 and a third is used to carry out an insulating rod 5 which can be moved in the direction of an axis 4 during a switching operation. One of two current connections 6 , 7, which can be brought to high voltage potential and are potential-shielded from the metal encapsulation 1 , are led through the partition isolators 2 , 3 . The power connections 6 , 7 are each electrically conductively connected to one of two fixed contact carriers 8 , 9 .

The contact carrier 8 has an axially extending opening (not designated), which serves to carry out a tubular running contact 10 , which is rigidly or articulatedly connected to the insulating material rod 5 and can be displaced along the axis 4 , of a movable switching element of the disconnector. The circumferential surface of the running contact 10 contacted to form a sliding contact 11, an example contact plates containing and arranged coaxially with the movable contact 10 contact part of the contact carrier. 8 The contact carrier 8 is designed as a shield at its end facing the contact carrier 9 and carries at its other end a shield 12 which is arranged concentrically to the axis 4 and which shields the end of the running contact 10 fastened to the insulating material rod 5 from the metal encapsulation 1 . The opposite end of the running contact 10 has a tubular section 13 which acts as a hollow contact and which serves for the sliding bearing of a spring-loaded follow-up contact 14 and for taking over a current possibly led by the follow-up contact 14 and attributable to a pre-ignition.

The contact carrier 9 is tulip-shaped at its end facing the contact carrier 8 and carries on its inside a contact 15, preferably formed by contact fingers and arranged concentrically to the axis 4 , of a fixed contact piece of the disconnector. This contact piece also has a pin-shaped pre-ignition contact 16 fastened in the bottom of the tulip-shaped contact carrier 8 and extending along the axis 4 .

The more detailed structure and mode of operation of the contact arrangement of the disconnector according to the invention are explained in more detail with reference to FIG. 2. From this figure it can be seen that the essentially pin-shaped follow-up contact 14 is guided in an electrically conductive manner on the inner wall of the tube section 13 by means of a sliding contact 17 forming at least part of its outer surface and on its end facing away from the pre-ignition electrode 16 of the fixed contact piece a compression spring 18 mounted in the interior of the running contact 10 is supported. The end of the compression spring 18 facing away from the follow-up contact 14 is mounted on a support 19 rigidly connected to the run contact 10 .

In the embodiment shown in Fig. 2 in the right half of the circuit breaker off position, the open switching pieces form an isolating distance T and the trailing contact 14 is guided by the slightly pre-stressed compression spring 18 against a stop 20 of the barrel contact 10.

When the disconnector is switched on, the insulating rod 5 is now guided downward in the direction of an arrow (not shown) under the action of a drive (not shown). The one with the 5 Isolierstoffstange rigid or articulated moving contact 10 and thus the follower contact 14 will now be passed over the shield acting as the separating section T part of the contact carrier 8 out into the separating section T. Any pre-ignition caused by residual charges and / or operating frequency voltage on the contact carriers 8 , 9 is initiated by the pin-shaped pre-ignition contact 16 extending along the axis 4 and the likewise pin-shaped follow-up contact 14 guided along the axis 4 . The current occurring here flows from the contact carrier 9 via the pre-ignition contact 16 , the pre-ignition spark (not shown), the wake contact 14 , the sliding contact 17 , the running contact 10 , and the sliding contact arrangement 11 to the contact carrier 8 . A transverse breakdown during the particularly critical pre-ignition phase is avoided with great certainty since leader discharges which form in the pre-ignition phase are axially centered by the pre-ignition contact 16 and the wake contact 14 . A change in the dominant axial distribution of the electrical field of the isolating switch into an undesirable dominant radial field distribution, which leads to an undesirable transverse breakdown, is thus avoided.

In the course of the further switch-on process, the wake contact 14 hits the pre-ignition contact 16 . The trailing contact 14 is now moved against the force of the compression spring 18 in the tube section 13 of the running contact 10 . In this case, the compression spring 18 is tensioned and the current which may still be flowing continues to be conducted via the sliding contact 17 to the running contact 10 . Finally, the running contact 10 contacts the fixed contact 15 and the switch-on position shown in the left half of FIG. 2 is reached, in which the fixed contact 15 and the running contact 10 form a continuous current path bridging the pre-ignition contact 16 and the follow-up contact 14 .

This isolating switch can be seen to have an axial isolating switch geometry which is comparable to the axial isolating switch geometry of an isolating switch without an overrun contact 14 which substantially reduces the risk of breakdowns. Compared to a disconnector with a follow-up contact built into the fixed contact piece according to the prior art and also substantially reducing the risk of transverse breakdowns, the disconnector geometry is considerably reduced in the axial direction. Only a fixed pre-ignition contact 16 , which is therefore only slightly extended in the axial direction, is required on the fixed contact piece. The trailing contact 14 , which takes up a relatively large amount of space in the axial direction, on the other hand, is built into the running contact 10 , which offers sufficient space.

An additional reduction in the disconnector geometry in the axial direction is achieved if the disconnector does not have an integral contact 10 , but - as can be seen in FIG. 3 - is constructed telescopically. The running contact 10 has in this embodiment of the invention at least two contact tubes 21 , 22 , of which an inner contact tube 21 having the tube section 13 for receiving the follower contact 14 is guided in an outer contact tube 22 by means of a sliding contact 23 in an electrically conductive manner. The outer contact tube 22 is mounted in an electrically conductive manner in the axial direction in the contact carrier 8 and has at its two ends two inwardly directed stops 24 , 25 spaced apart in the axial direction. The inner contact tube 21 has a projection 26 which interacts with the stops 24 , 25 when switching on and off.

When this disconnector is switched on, the insulating rod 5 is guided downward in the direction of the arrow in accordance with the embodiment according to FIG. 2 (right half of FIG. 3). The inner contact tube 21 of the running contact 10 , which is rigidly or articulatedly connected to the insulating rod 5, and thus also the follow-up contact 14 , which is slightly biased by the compression spring 18, are now guided into the separating distance T via the part of the contact carrier 8 acting as a shielding of the separating distance T. Any pre-ignition caused by residual charges and / or operating frequency voltage on the contact carriers 8 , 9 is initiated by the pre-ignition contact 16 and the wake contact 14 . The current occurring here flows from the contact carrier 9 via the pre-ignition contact 16 , the pre-ignition spark (not shown), the wake contact 14 , the sliding contact 17 , the inner contact tube 21 , the sliding contact 23 , the outer contact tube 22 and the sliding contact arrangement 11 to the contact carrier 8 . In this case, a transverse breakdown is avoided in accordance with the embodiment according to FIG. 2.

In the course of the further switch-on process, the overrun contact 14 according to the embodiment according to FIG. 2 is displaced by the pre-ignition contact 16 against the force of the compression spring 18 in the tube section 13 of the contact tube 21 . In this case, the compression spring 18 is tensioned and the current which may still be flowing continues to be conducted via the sliding contact 17 to the inner contact tube 21 . At the same time, the shoulder 26 22 provided on the inner contact tube 21 takes with it. The downward movement of the outer contact tube 22 can be limited by a projection 27 provided at its upper end and directed outwards. Finally, the contact tube 21 of the running contact 10 contacts the fixed contact 15 and thus the switch-on position shown in the left half of FIG. 3 is reached, in which the fixed contact 15 and the inner contact tube 21 form a continuous current path bridging the pre-ignition contact 16 and the follow-up contact 14 .

When switched off, the insulating rod 5 is moved upwards. In the course of the upward movement of the insulating rod 5 and thus also the contact tube 21 , the compression spring 18 relaxes. The spring-loaded follow-up contact 14 contacts the pre-ignition contact 16 until the inner contact tube 21 has released the fixed contact 15 . The follow-up contact 14 is then carried along by the stop 20 . Any reignitions that may occur when switching off can therefore only occur between the axially centered electrodes of follow-up contact 14 and pre-ignition contact 16 . In the course of the further upward movement, the shoulder 26 carries the outer contact tube 22 upward when it hits the stop 24 . The upward movement of the contact tube 22 is limited by a stop 28 attached to the contact carrier 8 .

In this embodiment of the invention, the running contact in the switch-off position is shortened compared to the running contact in the embodiment according to FIG. 2 in accordance with the stroke of the outer contact tube 22 . Accordingly, the shield 12 of the running contact 10 with respect to the metal encapsulation 1 can be formed in a correspondingly shortened manner.

Label list

1 metal encapsulation
2, 3 bulkhead isolators
4 axis
5 insulating rod
6, 7 power connections
8, 9 contact carrier
10 running contact
11 sliding contact arrangement
12 shielding
13 pipe section
14 overrun contact
15 fixed contact
16 pre-ignition contact
17 sliding contact
18 compression spring
19 support
20 stop
21, 22 contact tubes
23 sliding contact
24, 25 stops
26, 27 approaches
28 stop
T separation distance

Claims (10)

1. Disconnect switch for a metal-encapsulated gas-insulated high-voltage system with two switching elements arranged in the insulating gas-filled metal encapsulation ( 1 ) and contactable or separable along an axis ( 4 ) with a pin-shaped, axially extending pre-ignition contact ( 14 , 16 ), which is in one of the two switching elements is formed as a follower contact (16), and with a the Vorzündkontakt (16) a fixed two switching pieces coaxially surrounding the fixed contact (15) and a provided on a mobile two contact members movable contact (10) which in the oN position with the fixed contact (15) comprises Continuous current path, characterized in that the running contact ( 10 ) is tubular and has a tubular section ( 13 ) which acts as a hollow contact and which supports the slide bearing of the follow-up contact ( 14 ) and the takeover of a possibly led by the follow-up contact ( 14 ) to a Vo ignition serves to be returned current. 2. Disconnector according to claim 1, characterized in that the pin-shaped follow-up contact ( 14 ) with its dumbbell surface is guided in an electrically conductive manner on the inner wall of the tube section ( 13 ) and on its end facing away from the pre-ignition electrode ( 16 ) of the fixed contact piece on one in the interior of the barrel contact ( 10 ) supported compression spring ( 18 ) is supported. 3. Disconnector according to claim 2, characterized in that the compression spring ( 18 ) with its end facing away from the follow-up contact ( 14 ) is mounted on a support ( 19 ) rigidly connected to the run contact ( 10 ). 4. Disconnector according to one of claims 2 or 3, characterized in that the follow-up contact ( 14 ) in the switch-off position is guided by the prestressed compression spring ( 18 ) against a stop ( 20 ) of the running contact. 5. Disconnector according to one of claims 1 to 4, characterized in that the running contact ( 10 ) is integrally formed. 6. Disconnector according to one of claims 1 to 4, characterized in that the running contact ( 10 ) is telescopic. 7. Disconnector according to claim 6, characterized in that the running contact ( 10 ) contains at least two contact tubes ( 21 , 22 ), of which a first contact tube ( 21 ) forming the hollow contact is guided in the second contact tube ( 22 ) in an electrically conductive manner . 8. Disconnector according to claim 7, characterized in that the second contact tube ( 22 ) has at least two stops directed into the tube ( 24 , 25 ), of which a first stop ( 24 ) when switching off and an axially spaced from the first second stop ( 25th ) interacts when switched on with an attachment ( 26 ) provided on the first contact tube ( 21 ). 9. Disconnector according to claim 8, characterized in that means are provided to limit the movement of the second contact tube ( 22 ) in the axial direction to a predetermined stroke. 10. Disconnector according to claim 9, characterized in that the means have an attached to the second contact tube ( 22 ), outwardly directed extension ( 27 ) and a fixed stop ( 28 ).