EP0187951A1 - Switch contact for a vacuum switch - Google Patents

Abstract

To generate an axial magnetic field over the contact surfaces in vacuum interrupters, conductor loops are arranged behind the contact pieces, which are constructed similar to a spoke wheel. In order to dimension such conductor loops with a small cross-section and to be able to manufacture them easily, it is proposed that the conductor loops (11, 12) contain at least approximately sector-shaped connections (6, 7) that these connections (6, 7) merge into webs (10) and that successive connections (6, 7) in the circumferential direction are alternately electrically conductively connected to the end face of a contact pin or to the contact face of a contact piece.

Description

The present invention relates to a switch contact for a vacuum interrupter according to the preamble of claim 1.

Such a vacuum interrupter is known from US Pat. No. 4,196,327. From this patent, two embodiments can essentially be found, one of which allows the current in the region of the outer periphery to pass into a contact piece, while the second leads the current back into the vicinity of the axis of rotation of the contact and there passes into corresponding contact surfaces of the contact piece.

The first of the above-mentioned embodiments, which allows the current to pass into the contact piece in the region of the outer circumference of the conductor loop, results in a field strength of the axial magnetic field which is dependent on the distance of the arc from the edge of the conductor loop. This non-uniformity in the magnetic field is not desirable. The second embodiment avoids this unevenness of the magnetic field, but is relatively complex to manufacture, since a horizontal slot must be made within a ring, for which a special tool is required. On the other hand, this embodiment does not allow dimensioning to the highest load on the material, since the webs leading to the center of the ring and thus to the contact surfaces can have only a small part of the height of the conductor loops in the region of the circumference. A very wide design of the webs would inadmissibly reduce the area penetrated by the axial field. In this embodiment, a weight of the conductor loop which is high in comparison to the power must therefore be accepted. The present invention has for its object to make a switch contact according to the preamble of claim 1 easier to manufacture, to make the conductor loops mechanically stable and thereby reduce their weight with the same size and load capacity of the contact piece and a large part of the contact area with the generated axial field capture.

This object is achieved by the characterizing features of claim 1. Due to the arrangement of the connections of the conductor loops distributed over the end face of the contact bolt or over a corresponding contact surface of the contact piece, the webs of the conductor loops can have an extension in the axial direction that is independent of the height of their part remote from the axis. Their cross-sections can therefore be designed for the maximum current load in each section.

Within the limits of the load-bearing capacity of the contact surfaces, the slots that separate the contact surfaces can also be placed obliquely or asymmetrically, provided that contact surfaces lying next to one another only in the circumferential direction and support surfaces arise on the non-contacted end face. Simple manufacture is ensured if the slots are parallel to a plane which contains the axis of rotation of the switching contact. A symmetrical and therefore particularly highly resilient embodiment is achieved if the plane of symmetry of the slots contains the axis of rotation of the switching contacts. In order to be able to advantageously transmit the mechanical forces during the switching process, an embodiment is advantageous in which intermediate layers with low electrical conductivity are arranged on the side of the connections which is not contacted with low resistance. Such intermediate layers can consist of ceramic or also of high-resistance metals, for example of stainless steel. From a mechanical point of view, they are only subjected to pressure.

The conductor loops advantageously consist of a common circular ring and webs integrally formed thereon, the webs having the same extent in the axial direction as the circular ring. The webs preferably have twice the width of the circular ring, so that the webs and the circular ring are equally loaded when all loops are subjected to a uniform current.

In order to maintain a flat surface of the conductor loops and to allow the smallest possible space to the contact piece, it is advantageous if the support surfaces are set back in the axial direction with respect to the surface of adjacent connections and if the intermediate layers are flush with the adjacent connections in the axial direction . The intermediate layers are advantageously used in the form of platelets in corresponding depressions or the recessed parts of the connections. The recessed parts of the connections can be formed by machining deformation, by stamping or, if necessary, when casting the conductor loops.

If the contact pin essentially has to be dimensioned according to the current carrying capacity, not so much according to the mechanical strength, it is advantageous that a part with an enlarged cross section adjoining the end face is formed on the contact pin and that the connections of the conductor loops cover this enlarged cross section. As a result, thermal overloading of the material is avoided in the area of the current transfer from the contact pin to the connections of the conductor loops, although only a part of the end face of the contact pin is available for low-resistance contacting of the connections in this area.

• Fig. 1 zeigt einen erfindungsgemäßen Schaltkontakt in teilweise gebrochener Ansicht,
• Fig. 2 bis 4 zeigen erfindungsgemäße Anordnungen von Leiterschleifen in Draufsicht bzw. in einem radialen Schnitt.

The invention will now be explained in more detail with reference to four figures. It is not limited to the examples shown in the figures.

• 1 shows a switch contact according to the invention in a partially broken view,
• 2 to 4 show arrangements of conductor loops according to the invention in plan view or in a radial section.

A contact pin 1 has a part 13 adjoining its end face 14 with an enlarged cross section. An arrangement 2 of conductor loops 11, 12 is applied to the end face 14 of the contact bolt 1. The connections 6 of the conductor loops 11, 12 are electrically conductively connected to the end face 14 of the contact bolt 1, for example welded onto the end face 14. A contact piece 3 is placed on the arrangement 2 of conductor loops 11, 12. The contact piece 3 is electrically conductively connected to the connections 7 of the conductor loops 11, 12, for example welded (FIG. 2).

The connections 6, 7 are mechanically supported via electrically poorly or non-conductive intermediate layers 8 against the end face 14 of the contact pin 1 or against the contact piece 3 on their sides which are not connected to the contact piece or the contact pin, the support surfaces 24. The intermediate layers 8 can consist of ceramic or of poorly conductive metal. They are only subjected to pressure in the embodiment according to the invention, so that no special requirements with regard to their strength have to be made of the material of these intermediate layers.

The embodiment shown results in four conductor loops, each of which two conductor loops lying opposite one another with respect to the axis of rotation of the contact generate a magnetic field of the same direction and are therefore numbered 11 and 12 with the same designation. The adjacent conductor loops create a magnet field of opposite direction. With this arrangement, the individual conductor loops 11, 12 do not have to be insulated from one another, so that the compact, mechanically fixed embodiment according to the invention is possible. The number of conductor loops generated in this way is basically not limited. For example, two semicircular conductor loops can advantageously also be formed.

In the example shown, a pot contact 3 with an obliquely slotted cylinder wall and a contact disk 4 is shown as the contact piece, the contact disk 4 being a circular disk or a ring with a coaxial hole that is relatively small compared to the circumference. Instead of the slotted pot contact, a plate contact can also be used, for example, whereby the overall height of the contact and thus its mass can be reduced.

The arrangement of the slots 9 between the individual connections 6, 7 makes them easy to manufacture. of contact guaranteed and at the same time opens up the possibility of aligning the extension of the webs 10 in the axial direction with the extension of the ring regions 5. In the example shown, the connections 6, 7 with the intermediate layers 8 and the conductor loops 11, 12 have the same dimensions in the axial direction. Not only is it possible to make contact with flat surfaces of the connecting bolt or the contact piece, but also a very small distance from the contact piece. This results in a relatively large field strength in the axial direction in the region of the contact surface, in particular in the case of flat contact pieces.

The coaxial bore 16 serves as a centering bore when welding or soldering the conductor loops onto the contact bolt or the contact piece. The bore 16 can also serve to hold a fastening screw which connects the contact piece and the conductor loops with the contact bolt.

An embodiment with great mechanical stability and a small electrical shunt to the conductor loops through the intermediate layers is provided if the intermediate layers according to FIG. 4 are formed in one piece for two connections 20, 21 opposite each other with respect to the contact axis and the shape of two ring sectors 18 have, which are connected to each other by a web 19 enclosing the contact axis 17. A bore 16 in the web 18 and in the connections 20 to 23 below it serves to center the intermediate layer 18 and 19, the connections 20 to 23 and possibly the contact piece 3 and the contact pin 1.

9 claims

4 figures

Claims (9)

1. Switching contact for a vacuum interrupter with a device for generating an axial magnetic field, which has a contact pin and a contact piece with at least one contact surface and on the side facing away from the contact surface contains two or more conductor loops, the conductor loops above the contact surface in the axial direction generate a running magnetic field, the conductor loops starting from the contact bolt and leading back to a region of the contact piece close to the axis and separated from one another by a slot. Have connections, the connections of the conductor loops being supported by an electrically poorly or non-conductive support body in the direction and in the vicinity of the axis of the contact bolt, and the conductor loops being integrally connected to one another at least in their part remote from the axis, characterized in that the conductor loops (11 , 12) contain at least approximately sector-shaped connections (6, 7) that these connections (6, 7) merge into webs (10), each of which belongs to two adjacent conductor loops (11, 12) and that connections (6, 7 ) are alternately electrically conductively connected to the end face (14) of the contact bolt (1) or to the connection face (15) of the contact piece (3) and that the slots (9) between the connections (6, 7) make contact with the low resistance. Disconnect the relatively high-resistance contact surfaces (24) on the opposite side. 2. Switching contact according to claim 1, characterized in that the slots (9) are parallel to a plane which contains the axis of rotation of the switching contact. 3. Switching contact according to claim 2, characterized in that the plane of symmetry of the slots (9) contains the axis of rotation of the switching contacts. 4. Switching contact according to one of claims 1 to 3, characterized in that intermediate layers made of a non-conductive or poorly conductive material are arranged on the supporting surfaces of the side of the connections which is not contacted with low resistance. 5. Switching contact according to one of claims 1 to 4, characterized in that the conductor loops form a common circular ring and integrally formed webs and that the webs have the same extent in the axial direction as the circular ring. 6. Switching contact according to claim 5, characterized in that the webs are twice as wide as the circular ring. 7. Switching contact according to one of claims 1 to 6, characterized in that the connections have recessed support surfaces in relation to the surface of adjacent connections in the axial direction and that the intermediate layers terminate in the axial direction in a plane common to the adjacent connections. 8. Switching contact according to claim 7, characterized in that intermediate layers for two mutually opposite connections are formed in one piece with respect to the contact axis and have the shape of two ring sectors which are connected to one another by a web running through the contact axis. 9. Switching contact according to one of claims 1 to 8, characterized in that the contact bolt is an integrally formed on the end face part with an enlarged cross-section and that the connections of the conductor loops cover this enlarged cross-section.

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