DE4112113A1 - Vacuum switch contact arrangement with two current guides - is for long-term and short-term guidance of arc current struck between oppositely moving coaxial electrodes - Google Patents

Abstract

Diffuse arcs of circuit-breaking current are struck paraxially between electrodes (6, 6') formed on the facing ends of hollow cylindrical current guides (3, 3'). Winding sections (5, 5') are arranged within the walls (12, 12') of the cylinders in the same direction, leaving gaps (9, 9') at an angle of 75 deg. to the axis. The contacts (1, 1') are driven apart so that arc current transferred from long-term to short-term current guides remains diffused until cut off at a zero-crossing. ADVANTAGE - Construction is simplified and switching of initial arc to insignificantly smaller electrode surface is accelerated.

Description

The invention relates to a contact arrangement for Vacuum switch with the in the preamble of claim 1 specified features.

State of the art

A contact arrangement which corresponds to the preamble of patent claim 1 is known from DE 32 27 482 A1. There is a pair in the associated subject matter of the invention mutually axially movable associated hollow cylindrical Current carrying body in the walls with the hollow cylinder axis slots slanted at the same angle, the turn sections with the same turn sense arise to let; and those facing the switching path End faces are through contact and electrode bodies covered.

These current carrying bodies both have longer currents Duration - d. s. Operating current as well as one-second and / or Three-second current - as well as just a few alternating current periods permanent short-circuit breaking current. In addition, the hollow cylinder walls transmit the force to Production of the contact pressure.

The design has these different functions one and the same component with the resulting ones Stresses to take into account what is particular disadvantageous for large operating and short-circuit currents can affect:  

This results in the continuous current flow combined in one component and magnetic field generation a relatively high electrical Resistance, the square of the cosine of the angle of inclination the turn sections are proportional is; at an angle of inclination of at least 70 degrees is the resistance of the current guiding body slotted in this way already around nine times the unslit one.

Establishing sufficient contact pressure on the large contact and electrode discs required a great force through the slotted hollow cylinder walls should be transferred. As in DE 32 27 482 A1 already suggested, the hollow cylinder walls relieve the contact force transmission through the support body, however, this is an additional constructive effort connected.

It has also been suggested that the contact arrangement thereby reducing the contact pressure to be exerted and thus make the support body superfluous, by the contact area of the contact and electrode disc reduced to a circular surface by concave formation becomes. And for the solution of the existing one Problem of the relatively large resistance of the still multifunctional Current carrying body has been proposed the magnetic field generation entirely in the wall of the then bowl-shaped or cup-shaped contact and To lay the electrode body: DE 39 15 519 C2. Here is, however, because of the series connection of the now fully executed Wall of the hollow cylindrical continuous current guide body with which the magnetic field is generated by the breaking current a second one coaxial shell wall required to use the as To prefer the electrode serving tray bottom to the switching distance.  

The desired significant reduction in electrical Resistance of this contact arrangement is also associated with additional constructive effort; the electrode area is also reduced.

Furthermore, they are circular sector-shaped, becoming one not completely closed ring complementary winding sections known for generating an axial magnetic field, the approaches parallel to the axis at one end have on which a contact and electrode disc is arranged: DE 24 43 141 A1. In DE 40 13 903 A1 then suggested these winding sections in one hollow cylindrical current carrying body by vertical and to produce gaps parallel to the axis. But because the entire power supply and the magnetic field generation are united again in one component the problem of the relatively high electrical resistance and the resulting considerable heat production away. A support body is also required for sufficient contact pressure on the equally large area Contact and electrode disc. And this support body cannot - as with hollow cylindrical current carrying bodies possible with winding sections inclined to the axis - save at least up to average nominal currents by reducing the circular contact and electrode area on an annular.

Object of the invention

To improve a generic contact arrangement for vacuum switches the electrical resistance of the System for generating the axial magnetic field during the guidance of the continuous current can also be eliminated, however, in such a way that the constructive training is simplified and the commutation of the initial arc of the Breaking current to an insignificantly reduced Electrode surface is accelerated.  

Solution of the task and associated advantages

The above task is in a generic Contact arrangement for vacuum switch through the characterizing features of claim 1 solved. Features of advantageous developments are in the subclaims 2 to 11 described.

The structure of the contact arrangement according to Long-term and short-term functions generally enable a constructive simplification. The contact arrangement is now composed of only two components: a) a bowl-shaped, open current carrying body for Guiding the continuous current and b) one within the continuous current guide body arranged on the control track side current carrying body provided with an electrode body for the exclusive management of the breaking current with simultaneous generation of magnetic fields. This simple one Structure of the contact arrangement with which regarding the switching path have both axial and radial magnetic fields generated, does not mean a basic completion of a already existing production of shell contact arrangements either a) to generate a radial magnetic field, around the breaking current arc along the To rotate circumference, or b) to generate a axial magnetic field to the breaking current arc keep diffuse. Accordingly, the effort for the production launch small. The latter also applies to the case of an existing production of Axial magnetic field contact arrangements, which are annular sector-shaped Winding sections for magnetic field generation serve. The suggested contact arrangement is with both systems of power supply and magnetic field generation compatible.  

External radiators on the vacuum switch tube for discharge the heat of electricity can be reduced because of its considerable save up to high current ratings or at least significantly reduce it.

In the case of the use of bowl-shaped current guiding bodies for the generation of axial magnetic fields there is also the fact that the current-interrupting effect of the axial magnetic field is supported by the anode potential effect.

Also for the commutation of the arc of the breaking current from the continuous current guide bodies to the switch-off current guide bodies are more favorable conditions by now between the components on which the arc current commutate, there is a voltage difference.

Embodiments

Embodiments of the invention are based on Drawings explained; it shows:

Fig. 1 pair of contact pieces in sectional view

Fig. 2 plan view of the bottom switching member of Fig. 1

Fig. 3 switching piece in partial sectional view

Fig. 4 top view of the switching member of FIG. 3.

In Fig. 1, a pair of contact pieces 1 ', 1 according to the invention is drawn during a power interruption within a switch housing, not shown, by a drive, also not shown. The diffuse arc of the breaking current indicated by fine lines parallel to the axis burns between the covers of the hollow cylindrical first current-carrying bodies 3 ', 3 serving as electrode bodies 6', 6 .

These bodies are only intended for guiding the breaking current and therefore do not give any contact. In the hollow cylinder walls 12 ', 12 turn sections 5', 5 are arranged, which have the same winding sense on both current carrying bodies. The wall gaps 9 ', 9 , which allow the winding sections to form and enclose angles of 75 degrees with the contact piece axis , are indicated for the case of open gaps with a clear extent in the circumferential direction for reasons of simplification of the drawing by the center lines. The gaps can also be narrow and filled with an electrically poorly conductive or insulating layer; then the center line indicates this layer. The hollow cylinder of the first current carrying body are inserted with the end facing away from the switching path in annular grooves 10 ', 10 in the bottoms of the second current carrying body 4', 4 . These floors can also represent independent components as supporting bodies. The second current-carrying body 4 ', 4 , which surround the first current-carrying body 3', 3 , only have to carry continuous currents, including the short-time current. They also represent hollow cylindrical bodies with solid walls 12 ', 12 and floors 11', 11 . In addition to the ring grooves 10 ', 10 there are also flat cylindrical depressions in the bottoms for connection to the current conductor bolts 2', 2 . In a manner not shown, in particular radial slots for eddy current damping can be provided in the bottoms 11 ', 11 .

The circular ring surfaces of the open end faces - see Fig. 2 - serve as contact surfaces 13 ', 13 ; in a manner not shown, the contact surfaces with material such. B. be plated or coated from chrome copper to prevent welding.

When contact is interrupted in between the power line through one Electric arc.  

So that its base points commute as quickly as possible on the electrode body 6 ', 6 , the end faces of the hollow cylinder walls have bevels 7', 7 on the outside. On the inside, approximately in the plane where the bevels begin, notches 8 ', 8 are available. This results in a current loop already in the switched-on state, which increases after the contact separation by the initial arc jumping the annular gaps 14 ', 14 electrodynamically towards the contact piece axis and thus as desired on the electrode body 6', 6 of the first current-carrying body 3 ', 3 . There, the breaking current arc is kept in a diffuse state by the self-generated axial magnetic field.

The second current carrying body 4 ', 4 can be made of OFHC copper to complete their already low-resistance design. The first current-carrying body 3 ', 3 for the exclusive guidance of the breaking current need to carry this current for a maximum of two current semi-oscillations. Therefore, a material with relatively higher resistivity and greater mechanical strength, e.g. B. also non-magnetic steel can be used. It can be useful to plate or coat the electrode surfaces with a metal or with a metal combination that has particularly good properties with regard to the interruption of the arc current, such as. B. Chrome copper.

When using an electrode material in comparison radial resistance to copper can be higher Slots for damping eddy currents advantageously saved will. This saving is also possible if at Use of copper as an electrode material is appropriate small slice thickness is selected.  

The drawings of FIGS. 3 and 4 show an embodiment with first current-carrying bodies, the winding sections of which are inclined at an angle of 90 degrees to the contact piece axis; only the lower 20 of the two identical switching pieces is shown. Corresponding to the 90 degree inclination, circular ring sectors form the winding sections 21 . For connection to the electrode disk 24 on one side and to the bottom 11 of the second current-carrying body 4 on the other, the winding sections each have ends 22 and 23 pointing approximately axially parallel in opposite directions at the end regions.

In total, the individual winding sections form the first current-carrying body 25 as a ring structure. Because of the need to insert the winding sections in parallel circuits, the ring structure has system-related gaps 26 on the circumference. In this context, it can be advantageous to have the two contact pieces facing each other in such a way that the gaps in the ring structure of one first current-carrying body are covered by winding sections in the ring structure of the other first current-carrying body.

The 90 degree slope of the winding sections of the first Current carrying body also results in a significantly reduced Wall height of the second current carrying body relative to the Current guiding bodies of the first embodiment.

The electrode disk 24 has a convex central region 27 , the tip of which protrudes somewhat from the plane through the contact surfaces 13 of the second current-carrying body 3 . In the switched-on state, the tips of the two electrode disks touch and are pressed in to such an extent that the main contact can arise through the contact surfaces 13 of the second current-carrying bodies.

When switching off, the tops of the Electrode disks after disconnection of the main contact and the initial arc already occurs within the axial magnetic field. It can be beneficial for the Origin of the initial arc on the electrode disks to provide fire-resistant material.

Instead of a central spherical cap-shaped curvature the electrode discs with circular surface contact when switched on Condition can be the curvature of the electrode discs also partially toroidal, so that coaxial convex ring structures arise. In the on The contact is made on a circular pressure surface, being different by varying their radial Location for the initial arc an optimal place of origin between the edge of the electrode and the center of the electrode leaves.

In addition to the first embodiment, Fig. 1 and 2, the following is noted: If with unchanged second current guiding bodies 4 ', 4 z. B. the winding sections of the lower first current-carrying body 3 receive a winding sense in a manner not shown, which is opposite to the winding sense of the winding sections of the upper first current-carrying body 3 ', 3 , a radial magnetic field is generated with respect to the switching path. This magnetic field causes a contracted arc current to rotate after its commutation from the second to the first current guiding bodies on electrode bodies, now not shown, in the form of a circular disk, and in this way causes the current to be interrupted.

Claims (12)

1. Contact arrangement for vacuum switch, with

• a) axially opposed switching pieces that are movable relative to one another along a common axis;
• b) system of coaxial winding sections, to which electrode bodies are connected on the switching path side;

characterized by the following features:

• c) the systems of winding sections with adjoining electrode bodies on the switching path side represent first current-carrying bodies ( 3 ′, 3 ) or ( 25 );
• d) hollow cylindrical, on the switching path side contact areas ( 13 ', 13 ) having second current-carrying bodies ( 4', 4 ) surround the first current-carrying bodies at a distance from annular gaps ( 14 ', 14 );
• e) the first and second current carrying bodies are arranged with their end faces facing away from the switching path on a respective supporting body of the switching pieces ( 1 ', 1 ).

2. Contact arrangement according to claim 1, characterized by the following feature: the support body of the switching pieces ( 1 ', 1 ) or ( 20 ) simultaneously represent the bottoms ( 11', 11 ) of the second current carrying body. 3. Contact arrangement according to claim 1 or 2, characterized by the following features: the first current carrying bodies are represented by hollow cylindrical bodies ( 3 ', 3 ), the walls of which are formed by winding sections ( 5', 5 ) inclined to the hollow cylindrical axis ( 9 ', 9 ) have, where the electrode body is connected on the switching path side and the end face of the first current-carrying body is inserted into the supporting body of the contact pieces on the current conductor pin side. 4. Contact arrangement according to claim 1 to 3, characterized by the following features: the winding sense of the winding sections ( 5 ' ) of the first current-carrying body ( 3' ) on the contact piece ( 1 ' ) and the winding sense of the winding sections ( 5 ) of the first current-carrying body ( 3 ) on the switching piece ( 1 ) are opposite to each other. 5. Contact arrangement according to claim 4, characterized by the following feature: the winding sections of the first current-carrying body ( 3 ', 3 ) adjoining electrode body are designed in the form of an annular disk. 6. Contact arrangement according to claim 1 or 2, characterized by the following feature: the first current-carrying bodies ( 25 ) are represented by annular sector-shaped, coaxial winding sections ( 21 ), each of which has ends ( 22 ) on the switching path side, to which an electrode body is connected, while lugs ( 23 ) attached on the other end region connect to the supporting bodies of the switching pieces. 7. Contact arrangement according to claim 1 or 2, 3 and 6, characterized by the following features: the winding sections ( 5 ', 5 ) and ( 21 ) of the first current carrying body ( 3', 3 ) and ( 25 ) on the switching pieces ( 1 ' , 1 ) and ( 20 ) have the same winding sense. 8. Contact arrangement according to claim 7, characterized by the following feature: the winding sections ( 5 ', 5 ) and ( 21 ) adjoining electrode body ( 6', 6 ) or ( 24 ) of the first current carrying body ( 3 ', 3 ) or ( 25 ) are circular disk-shaped. 9. Contact arrangement according to one of claims 1 to 8, characterized by the following features: the hollow cylinder walls ( 12 ', 12 ) of the second current carrying body ( 4', 4 ) have such a shape in the front end region on the switching path that, in the event of a contact separation, the breaking current arc is electrodynamic the contact areas ( 13 ', 13 ) is driven onto the electrode body of the first current-carrying body. 10. Contact arrangement according to claim 9, characterized by the following features: notches ( 8 ', 8 ) are attached to the inner sides in the vicinity of the contact areas ( 13', 13 ) on the hollow cylinder walls of the second current-carrying body, while bevels ( 7 ', 7 ), which extend radially over part of the contact areas. 11. Contact arrangement according to one of claims 1 to 8, characterized by the following features: the electrode body of the first current-carrying body ( 3 ', 3 ) have in the switched-on state of the contact pieces simultaneously with the second current-carrying body ( 4', 4 ) contact-giving areas which open during a switch-off process after the contact opening of the second current carrying body.