EP0176665A2 - Vacuum switch fully insulated by a solid substance - Google Patents

Abstract

The invention relates to a vacuum switch with two connections and an insulating housing, which carries an earthed coating and has a vacuum interrupter inside, wherein there is 14 gas between the vacuum interrupter 1 and the insulating housing 12, 13 with a metal coating. The vacuum switch is characterized in that in the insulating housing 12, 13 two control electrodes 19, 22 are arranged axially offset, which are at the potential of the connections. In addition, an additional third control electrode 20 is provided in the insulating housing 12, 13, which lies in the area of the switching chamber and assumes an intermediate potential between the connection potential and earth potential. With this concept, extremely high field strengths with a space-saving design are avoided. Furthermore, no partial discharges occur in the region of the gas between the vacuum interrupter chamber 1 and the insulating housing 12 and 13, which leads to considerably higher operational reliability.

Description

The invention relates to a fully solid-insulated vacuum switch (so-called 'switch pole') with two connections and an insulating housing, which carries an outer grounded coating and has a vacuum interrupter inside, gas being located between the interrupter and the insulating housing. Such vacuum switches with full solid insulation are preferably required for factory-made high-voltage switchgear or transformer stations, where there are high requirements with regard to protection against accidental contact and with regard to small-scale and compact construction.

It is known to use vacuum interrupters in switching devices which consist of an evacuated housing with a fixed and a movable contact piece and metal shields.

The fixed contact piece is attached to a fixed contact rod which is led out of the housing in a vacuum-tight manner by an insulator. The movable contact piece, on the other hand, is attached to an axially movable contact rod, which is led out in a vacuum-tight manner by an insulator and a metal bellows. Metal shields between 575-267.532EP-SF-Bk
arranged the isolators. There is either air (DE-PS 23 22 372) between the vacuum interrupter chamber and the insulating housing, or the intermediate space is filled with insulating oil (JP-PS 55-5651).

If air is provided in the space between the switching chamber and the insulating housing, then in spite of the field-controlling design of the connecting bodies, electrically highly stressed sections in which partial electrical discharges can occur cannot be avoided.

Switches with oil in the intermediate space in turn have similar disadvantages to the so-called low-oil switches because they pose a fire risk and endanger the environment. Furthermore, it is known to pour the complete vacuum interrupter in - epoxy resin (DE-OS 22 40 106). However, there are disadvantages because internal mechanical stresses acting on the vacuum interrupter are unavoidable, and cracks as well as air gaps and air inclusions cannot be reliably excluded, in which the formation of destructive partial electrical discharges then occurs.

The solid-air-insulated vacuum switches described above also have the additional disadvantage that they must not be touched during operation, and therefore, for reasons of the necessary protection against accidental contact, installation can only take place in metal-enclosed switch cells, or additional shut-offs are required. This disadvantage can be known simultaneous reduction in dimensions can be overcome if the principle of full solid insulation is applied, according to which the entire high-voltage current path and all built-in devices are embedded in solid insulating material, on the surface of which a grounded metallic shielding is attached (Elektrie "28.Jhrg. (1974 ), Issue 10, pp. 533 - 538).

The invention is based on the finding that it is important in the improvement of such vacuum switches according to the preamble of claim 1 to avoid partial discharges in the area between the switching chamber and the insulating material housing or in the insulating material housing itself by avoiding extremely high field strengths and short distances and protection against accidental contact To shift the electrical stress into the solid insulation.

The invention is accordingly based on the object of developing a vacuum switch according to the preamble of claim 1 so that partial discharges can be reliably avoided despite the arrangement of the vacuum interrupter in an insulating housing with a grounded coating in the gas-filled space between the interrupter and the insulating housing.

This object is achieved in a vacuum switch according to the preamble of claim 1 by the characterizing features. Advantageous embodiments are the subject of the dependent claims.

The inventive concept is explained in more detail below using an exemplary embodiment with reference to the drawings, each of which shows a vacuum switch according to the invention.

Fig. 1 shows a vacuum switch according to the invention with an insulating housing, which consists of two detachably connected parts and in which the electrodes articulated to the connection potential have a larger diameter in the overlap area than the third control electrode. The vacuum switch shown comprises a complete vacuum switching chamber 1, which consists of an upper, fixed switching contact piece 2 with an attached upper, fixed contact rod 3, a lower, movable switching contact piece 4 with a lower, axially movable contact rod 5 and a metal bellows 6. The switching contact pieces 2 and 4 with their contact rods 3 and 5 are located in an airtight and evacuated housing which consists of an upper insulator 7 and a lower insulator 8 and a metal screen 9 which is at free potential.

At the ends of the vacuum chamber there are a sliding contact 10 and a contact 11, which form the connections of the vacuum switch.

The vacuum interrupter 1 is accommodated in an upper, fully solid-insulated cylindrical insulating body 12 and in a lower, fully solid-insulated cylindrical insulating body 13, which form an insulating housing. The insulator 12 and 13 on carry an earthed metal covering 14 on their outer surface, are connected in a dielectrically tight manner by means of an elastic insulating ring 15 via clamping elements 16, the lateral squeezing of the elastic insulating ring 15 being prevented by an inner and an outer metallic limiting ring 17 and 18. An upper control electrode 19 with the potential of the upper contact 11 and a third control electrode 20 with the free intermediate potential of the metal screen 9 of the vacuum interrupter 1 are cast in the upper fully solid-insulated insulating body 12 such that the control electrode 19 is spatially between the grounded metal coating 14 and the control electrode 20 . The upper control electrode 19 can simultaneously serve for the mechanical attachment of the vacuum interrupter 1 to the upper, fixed contact rod 3, for example via threads. The upper contact rod 3 is pushed through the upper solid-insulated insulating body 12 to create the upper connection. The control electrode 19 is expediently made from a rotationally symmetrical sheet metal body and from a thick-walled cup-shaped base body, so that, in a known manner, favorable heat dissipation from the vacuum interrupter chamber 1 into the upper, fully solid-insulated insulating body 12 is made possible, from where the heat can be given off to the ambient air. The lower control electrode 22 with the potential of the lower connection is located in the lower fully solid-insulated insulating body 13; which consists of the lower contact rod 5, the sliding contact 10 and the switch lead 21, and the third control electrode 20 with the free intermediate potential of the metal screen 9 cast in such a way that the control electrode 22 is spatially between the grounded metal coating 14 and the control electrode 20. The axially movable lower contact rod 5, to which a suitable drive is coupled, is inserted into the sliding contact 10, which is connected to the switch connecting conductor 21 cast into the lower, fully solid-insulated insulating body 13. The sliding contact 10 can also give the vacuum interrupter 1 guidance against radial offset by suitable shaping. The control electrode 22 is in turn expediently made of a rotationally symmetrical sheet metal body and a thick-walled annular base body, so that, in a known manner, favorable heat dissipation from the vacuum interrupter chamber 1 and the sliding contact 10 occurs in the lower fully insulated insulating body 13, from where the heat can be given off to the ambient air .

The lower and upper part of the third control electrode 20 with the free intermediate potential of the metal screen 9 are electrically connected to one another via an inner limiting ring 18 and connected to the metal screen 9 of the vacuum interrupter chamber 1 via a suitable contact element 23, for example a spring. If necessary, however, this contact element 23 can be dispensed with if essentially the same intermediate potentials for the control electrode 20 on the one hand and the metal screen 9 on the other hand result from capacitive potential division in the fully solid-insulated insulating bodies 12, 13 and in the vacuum interrupter 1.

Fig. 2 shows a vacuum switch with an insulating housing, the housing parts are connected by gluing and in which the electrodes articulated to the connection potential have a smaller diameter in the overlap area than the third control electrode. The third control electrode 20, which is at a free intermediate potential, accordingly has a different position. The complete vacuum interrupter chamber 1 is provided in the same way as in FIG. 1 in a lower and an upper fully solid-insulated insulating body 12 and 13 and is connected to the sliding contact 10 and the control electrodes 18 and 22.

The two insulating bodies 12 and 13 are connected to one another in FIG. 2 by an adhesive joint 24. However, for better interchangeability of the vacuum interrupter chamber 1, the dielectric connection of the insulating bodies 12 and 13 can also be carried out analogously to FIG. 1 via an elastic insulating ring 15, clamping elements 16 and limiting rings 17 and 18. The essential difference of the vacuum switch of FIG. 2 compared to that of FIG. 1 lies in the different position of the control electrodes 19 and 22 with the potential of the switch connections with respect to the control electrode 20 with the free intermediate potential of the metal screen 9. The control electrodes 19 and 22 with the potential the switch connections and the control electrode 20 with the free intermediate potential of the metal screen 9 are cast into the fully solid-insulated insulating bodies 12 and 13 so that the control electrodes 19 and 22 are spatially between the grounded metal coating 14 and the control electrode 20. The tax electrodes 19 and 20 then need only consist of the thick-walled cup-shaped or ring-shaped base bodies. The inventive arrangement of the control electrode 20 with the free intermediate potential of the metal screen 9 in the insulating bodies 12 and 13 in addition to the control electrodes 19 and 22 with the potential of the switch connections ensures that the voltage distribution within the vacuum interrupter chamber 1 and its breaking capacity in the installed state by the grounded metal coating 14 is not disturbed, and the electric field strength in the air space between the vacuum interrupter 1 and the fully solid insulated insulating bodies 12 and 13 is reduced so much that at operating voltage - no harmful partial electrical discharges can occur in air.

Fig. 3 shows a vacuum switch with an insulating housing, which consists of three detachably interconnected parts, in which the electrodes articulated to the connection potential at least partially consist of coverings which are applied to separately manufactured insulating material parts which are coaxially joined together. The insulating housing consists in particular of an upper, fully solid-insulated cylindrical insulating body 12, a middle, fully solid-insulated cylindrical insulating body 24 and a lower, fully solid-insulated insulating body 13. The insulating bodies 12, 13 and 24, which have a grounded metal coating 14 on their outer surface, are made of elastic insulating material rings 15 Dielectrically tightly connected to one another via clamping elements. The upper insulating body 12 in turn consists of two individual parts 25 and 26 cast from casting resin, which, by means of semiconducting or conductive coatings, form part of the control electrode 27 on one part of their surface, which is closed at one end by an electrode ring 28, while the other end is applied to a further control electrode 19 which is at the connection potential. The control electrode 19 expediently consists of a rotationally symmetrical, thick-walled cup-shaped base body, so that, in a known manner, favorable heat dissipation from the vacuum interrupter chamber 1 into the upper, fully solid-insulated insulating body 12 is made possible, from where the heat can be given off to the ambient air. The middle insulating body 24 carries a substantial part of a control electrode 29 on its inner circumference. The lower insulating body 13 also consists of two individual parts 30 and 31, which, by means of semiconducting or conductive coatings, form part of the control electrode 32 on part of their surface, which in turn also forms part of the control electrode 32 an electrode ring 33 is closed, the control electrode 32 also being articulated to the connection potential. The third control electrode 29 consists essentially of the coating on the central insulating body 24 and of small coating surfaces 34 and 35 on the individual parts 30 and 31. The coatings are connected to one another and to the metal screen 9.

In the vacuum switches according to the invention, harmful partial discharges in the area between Vacuum interrupter and insulating housing as well as inside the insulating housing are safely avoided, since no extremely high field strengths can occur locally. Further advantages lie in the comparatively simpler manufacture of the parts of the insulating housing.

Claims (5)

1. Vacuum switch with two connections and an insulating housing (12, 13) which has an outer _; carries grounded covering (14) and has a vacuum interrupter (1) in its interior, gas being located between interrupter (1) and insulating housing (12, 13),
characterized in that two control electrodes (19, 22, 27, 32) are arranged axially offset in the insulating housing (12, 13) and are articulated to the potential of the closest connection ₇
and
a third control electrode (20; 29) is arranged in the area of the switching chamber in such a way that it assumes an intermediate potential between the connection potential and earth potential (FIGS. 1-3). 2. Vacuum switch according to claim 1, characterized in that the control electrodes (19; 22), which carry the respective connection potential, axially overlap with the third control electrode (20; 29). 3. Vacuum switch according to claim 1 or 2, characterized in that the insulating housing (12; 13) has a substantially hollow cylindrical shape, 575-267.532EP-SF-Bk consists of two parts and is electrically close together in the area of the shaft section (Fig. 1, 2). 4. Vacuum switch according to claim 1 or 2, characterized in that the insulating housing consists of essentially three detachably interconnected parts, an upper, a middle and a lower insulating body (12, 13 and 24), which are electrically tightly connected to each other , wherein the middle insulating body (24) carries or part of the third control electrode (29), while the upper insulating body (12) and the lower insulating body (13) as axially outer parts of the insulating housing, each consisting of two separately manufactured and coaxially arranged insulating material parts ( 30, 31 or 25, 26) are joined together, which carry conductive or semiconducting coatings on the mutually facing surfaces, which form the control electrodes (27, 32) which are articulated to the potential of the next connection in each case (FIG. 3). 5. Vacuum switch according to one of claims 1 to 4, characterized in that the third control electrode (20) in the region of the switching path is galvanically connected to a metal screen (9) of the switching chamber (1).

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