Vacuum interrupter with a switch contact piece

According to the invention, heat generated inside a vacuum interrupter (1) is to be extracted, essentially by means of the pins (7, 8) of the contact pieces (5, 6) and, in order to improve the transmission of heat, a first slide contact surface (18) of a slide contact arrangement is provided on a pin (7), whereby the first slide contact surface (18) is arranged on a first section of a pin (7) which comprises an enlarged circumference relative to the remaining sections of the pin (7).

This application is a national stage of International Application No. PCT/DE03/00583 which was published on Feb. 14, 2003, and which claims the benefit of priority to German Application No. 102 07 892.0 filed Feb. 20, 2002.

TECHNICAL FIELD OF THE INVENTION

The invention relates to a vacuum interrupter having a switching contact piece.

BACKGROUND OF THE INVENTION

A vacuum interrupter arrangement is disclosed, for example, in DE 35 29 386 A1. The first sliding contact face here is arranged on a thicker, first section and is electrically conductively connected to a second sliding contact face.

A further arrangement is disclosed, for example, in the laid-open specification DE 196 03 157 A1. The vacuum interrupter described in the laid-open specification has a switching contact. The switching contact is essentially formed from two switching contact pieces, one of the switching contact piece being movable. The movable switching contact pieces has, at its end which faces away from the switching contact, a strut which is passed in a gas-tight manner through the wall of the vacuum interrupter by means of an elastic bellows. Directly adjoining the wall which is interrupted by the movable switching contact piece is a fixed contact to which the movable switching contact piece is electrically conductively connected. For this purpose, a self-sprung contact element made of beryllium bronze is provided there and this contact element is in the form of a helical spring and extends around the strut of the movable switching contact piece. By means of the self-sprung contact element, the switching contact piece is electrically conductively connected to the fixed contact.

Such self-sprung contact elements in the form of helical springs ensure that sufficient electrical contact is made. Owing to the excellent electrical and thermal insulation of the vacuum located in the interior of the vacuum interrupter, there is essentially only the strut, which is passed to the outside, of the movable switching contact piece for the purpose of dissipating the heat produced at the contact point. The known self-sprung contact elements in the form of helical springs are, in addition to the transmission of electrical power, only suitable to a certain extent for transmitting and passing on heat to other modules. In particular in the case of the arrangement known from the laid-open specification DE 196 03 157 A1, transmission of thermal energy to the surrounding environment is only possible to a limited degree owing to the direct arrangement of the self-sprung contact elements on the vacuum interrupter.

SUMMARY OF THE INVENTION

The invention relates to a vacuum interrupter having a switching contact piece which has, at its end which faces away from the switching contact of the vacuum interrupter, a strut which is connected to a first sliding contact face which forms, with a second sliding contact face, a sliding contact arrangement, in which the strut has a first section having a greater circumference than the remaining sections of the strut, and the first sliding contact face is arranged on the first section.

The present invention discloses dissipating the heat produced in the interior of the vacuum interrupter more effectively.

The invention is achieved, in one embodiment, by the first section having through-openings.

Owing to its increased circumference, the contact face provided of the sliding contact arrangement is increased in size. This makes it possible to increase the number of points which are electrically and thermally connected between the first sliding contact face and the second sliding contact face. As the number of these points increases, the electrical load on each individual point is reduced and the transmission of thermal energy is improved. The first section having an increased circumference may be connected, for example, in an integral manner with the remaining parts.

The through-openings also increase the surface area which is available for dissipating current heat. Furthermore, the openings provide a way for a cooling medium to pass through. Such a cooling medium may be, for example, a gas or a fluid.

Advantageously, in one aspect, the through-openings in the first section to run from the end which faces away from the vacuum interrupter to that end which faces the vacuum interrupter.

During a switching procedure, the second section is moved in the manner of a piston through the medium surrounding it. In the process, this medium also flows through the openings. In particular in the case of disconnection procedures at high currents, such as short-circuit currents, for example, which bring about a high thermal load, the first section makes it possible to improve the cooling of the switching contact piece and of the strut.

In another aspect, the first section to be formed by an intermediate piece other than the strut.

Using an intermediate piece which forms the first section it is possible to retain the design for the struts of vacuum interrupters which is known per se. Depending on the technical boundary conditions of the field of application of the corresponding vacuum interrupters, using various intermediate pieces means that the circumference of the first section can be selected to be variable. One and the same vacuum interrupter having the corresponding strut of the switching contact piece can thus be used in different switching devices by using various intermediate pieces. The intermediate piece itself may likewise buffer-store and irradiate heat.

In one aspect, there is a drive apparatus to be coupled to the intermediate piece.

If the switching contact piece is coupled to a drive in order to move the switching contact piece, a corresponding coupling device is provided. If this coupling device is formed by the intermediate piece, this results in a very simple solution in design terms.

A further, advantageous embodiment may provide for the second sliding contact face to be arranged on a hollow body, in particular in the form of an armature.

Arranging the second sliding contact face on a hollow body makes it possible, in particular, for thermal energy to be transferred effectively from the first sliding contact face to the second sliding contact face. In the case of a very compact external form, the hollow body provides a large area of overlap between the two sliding contact faces. In comparison with individual, for example planar sections, such a hollow body also makes it possible to achieve a favorable dielectric design.

In still another aspect, the hollow body is made to at least partially retain the vacuum interrupter.

In addition to forming the second contact face of the sliding contact arrangement, it is advantageous if the hollow body at least partially retains the vacuum interrupter. By combining the means for making the electrical and thermal contact and for retaining, the number of necessary modules is reduced. Furthermore, a hollow body is suitable, owing to its large surface area, for emitting, in turn, thermal energy transmitted to it to its surrounding environment.

In order to have a positive effect on the emission of thermal energy from the hollow body, provision may also be made for the hollow body to have openings through which a medium may flow.

Such a medium may be, for example, a gas which is arranged around the vacuum interrupter and the hollow body. As other media, it is also possible to use fluid media, for example insulating oils. The openings in the hollow body make it possible for media to flow through the interior of the hollow body, thus providing for effective heat exchange. In order to have a favorable effect on the emission of heat, the surfaces of the heat-emitting modules can be provided with a coating. Such coatings are, for example, paint coatings which improve emission and/or increase the surface area.

Furthermore, in another aspect, at least one elastic contact element may be connected to the first sliding contact face.

If an elastic contact element is connected to the first sliding contact face, the number of points with which contact has been made between the first sliding contact face and the second sliding contact face can be increased in a simple manner. This improves both the electrical and the thermal contact between the two sliding contact faces. The contact elements are in the form of, for example, strips which are bent in the form of a ring and are made of an electrically conductive material. The strips have elastically sprung fingers which are, for example, stamped and impressed out of the strips.

One advantageous embodiment may also provide for the elastic contact element to be mounted in a groove which runs azimuthally around the longitudinal axis of the strut.

The elastic contact element may be positioned in a simple manner using a groove which runs in the form of a ring along the longitudinal axis of the strut. In particular in the case of an embodiment of the elastic contact element in the form of a ring, the contact element may be mounted such that it can move within the groove, but may be positioned such that it is fixed with respect to the first section.

DETAILED DESCRIPTION OF THE INVENTION

FIG. 1shows a vacuum interrupter1. The vacuum interrupter1is part of an interrupter unit of a switching pole of an electrical switch. The vacuum interrupter1has an insulating housing2and a first cover plate3and a second cover plate4. Arranged in the interior of the vacuum interrupter1is a first contact piece5and a second contact piece6. The first contact piece5and the second contact piece6form a switching contact. At the end of the first contact piece5which faces away from the switching contact, a first strut7is passed through the second cover plate4such that it can move. A second strut8bears the second contact piece6and positions it rigidly on the first cover plate3. In order to pass the first strut7in a gas-tight manner through the wall of the vacuum interrupter1, a bellows9is arranged between the first strut7and the second cover plate4.

The vacuum interrupter1is arranged within an insulating housing10. The insulating housing10is essentially cylindrical and has a ribbed section11on its outer surface. The end faces of the insulating housing10are sealed by a first closing armature12and a second closing armature13. The first and the second closing armature12,13are manufactured from an electrically conductive material and also serve the purpose of connecting the electrical conductors of a current path to be connected. The vacuum interrupter1is arranged in the interior of the insulating housing10. As an alternative to this, provision may be made for the vacuum interrupter1to be arranged in an electrically conductive housing. The vacuum interrupter1must then be mounted such that it is insulated with respect to the conductive housing. For the purpose of retaining the vacuum interrupter1and for making electrical contact with the contact pieces5,6, a first retaining armature14is connected to the first closing armature12, and a second retaining armature15is connected to the second closing armature13. The vacuum interrupter1is retained between the two retaining armatures14,15. The second retaining armature15has a hole through which a screw16is passed. The screw16presses the first cover plate3of the vacuum interrupter1against the second retaining armature15, and makes contact between the second contact piece6and the second closing armature13via the second strut8and the first cover plate3. The first retaining armature14positions the vacuum interrupter1in the axial and radial direction. Both the first retaining armature14and the second retaining armature15have, at their ends which face the vacuum interrupter1, beads26a, bwhich provide dielectric shielding. The interior of the insulating housing10is filled with an insulating gas.

The first retaining armature14is in the form of a hollow body which has a cylindrical recess in its interior. The first strut7protrudes into this cylindrical recess. At the end of the first strut7which faces away from the first contact piece5, the first strut7has an intermediate piece17. This intermediate piece17forms a first section having a greater circumference than the remaining sections of the strut7. The first section has a first sliding contact face18. The cylindrical inner wall of the first retaining armature14is in the form of a second sliding contact face19. The second sliding contact face19is mounted such that it is fixed with respect to the insulating housing10. The first sliding contact face18and the second sliding contact face19form a sliding contact arrangement. For the purpose of improving the electrical and thermal contact between the first sliding contact face18and the second sliding contact face19, the first section of the intermediate piece17has a first annular groove20aand a second annular groove20b. An annular, resilient contact element is inserted in each of the annular grooves20a,20b. The elastic contact elements improve the contact between the first sliding contact face18and the second sliding contact face19. The number of contact elements may be selected. Depending on the current load, one, two or more contact elements may be arranged on the intermediate piece17. As an alternative to this, provision may be made for the elastic contact elements to be mounted such that they are fixed to the second contact face19. In the exemplary embodiment illustrated inFIG. 1, the first section is formed by a separate intermediate piece17. Provision may be made for this intermediate piece17to be formed integrally as part of the first strut7.

At its end which faces away from the vacuum interrupter1, the intermediate piece17has a pin21. A drive rod22is connected to the pin21. This drive rod22transfers the movement of a drive (not shown in the FIGURE) to the intermediate piece17and thus to the first contact piece5via the first strut7. The arrow provided with the reference numeral23illustrates the movement of the first contact piece5when the switching contact is being closed.

The first retaining armature14has two or more openings24a, b, c, d. The insulating gas arranged in the interior of the insulating housing10flows through the openings24a, b, c, din the first retaining armature14. In order to have a favorable effect on the flow through the recess in the retaining armature14, the intermediate piece17has openings25a,25b. This makes it possible to produce a flow driven by convection in the interior of the first retaining armature14. The heat transmitted via the first strut7into the interior of the first retaining armature14can thus be dissipated in a simple manner to the outside. In addition, the outer surface of the first retaining armature14emits further heat radiation. Some of the heat is transmitted directly to the first retaining armature14from the first contact piece5via the first strut7, the intermediate piece17and the sliding contact arrangement and is emitted to its surrounding environment from the first retaining armature14. The heat produced is largely caused by I2R losses or by arcs formed between the first contact piece5and the second contact piece6during switching procedures.