CH647353A5 - ELECTRIC SWITCH, ESPECIALLY FOR DC. - Google Patents

Description

The present invention relates to an electrical switch, in particular for direct current, with a switching chamber formed from at least two insulating material walls, in which a movable contact bridge is arranged, and with at least two fixed contacts arranged at a certain distance from one another, the contact surfaces of the fixed contacts and the movable contact bridge are attached at least approximately symmetrically to the axis of movement of the contact bridge and the contact points between the two fixed contacts and the contact bridge are connected in series when switched on.

Very fast switching devices must be used to protect electrical power grids, generators and transformers etc. from overloads or short circuits. Since these are usually large switching capacities, the switch design must meet correspondingly high requirements.

Double break contacts for high-speed switches are known (cf. DOS 27 23 624), in which a bridge contact is moved by an actuating rod and corresponding contact points are optionally opened or closed. These arrangements have a relatively weak, magnetic blowing field, as a result of which the switching arc experiences a relatively long dwell time in the contact area and corresponding contact erosion is caused. Furthermore, in the case of high short-circuit currents, the low dynamic repulsive forces between fixed and moving contacts have a disadvantageous effect, which on the one hand causes slow contact separation and on the other hand increases the dwell time of the switching arc in the area of the contacts.

It is therefore an object of the invention to eliminate the aforementioned disadvantages and to provide an electrical switch in which the arc is extinguished quickly and with simple technical means and the service life of the switch is thus increased.

A switch constructed in accordance with claim 1 brings about an amplification of the magnetic blowing field immediately after the contact separation by the parallel, low-resistance current path (line).

Compared to the known, the solution according to the invention requires no or only a small amount of additional conductors and does not cause any additional ohmic losses which can be determined by a voltage drop across the switch during nominal current operation. However, the aforementioned effects take effect shortly after the first contact separation; the current commutates completely into the secondary path formed by the conductor due to the arc voltage.

Advantageous developments of the invention are described in the following dependent claims.

A switch designed according to claim 2 causes a rapid displacement of the switching arc in the direction of the quenching chamber and makes it easier to jump over the arc base point into the quenching chamber.

The embodiment according to claim 3 allows a targeted, accelerated expansion of the arc by almost any shape of the magnetic blow loop.

An embodiment according to claim 4 causes an increased magnetic field and thus increases the blowing effect.

A particularly advantageous embodiment is described in claim 5, as a result of which the blow magnetic field is concentrated uniformly into the arcing chamber.

An embodiment according to claim 6 gives the advantage of a contact opening delayed on one side, the magnetic blowing field being built up completely in the line before the second contact point is opened.

The embodiment according to claim 7 can be realized particularly economically.

An embodiment realized according to claim 8 likewise causes a contact opening delayed on one side and requires

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changes only a very simple form of the contact bridge.

An advantageous embodiment according to claim 9 uses the electrodynamic force occurring in the line in the form of a mechanical pulse for the initial acceleration of the contact bridge to be opened.

The embodiment according to claim 10 results in a particularly useful line for accelerated contact opening.

Exemplary embodiments of the invention are illustrated below with the aid of drawings.

It shows

1 shows a DC high-speed switch with a line designed as a blow loop outside the switching chamber, in the switched-off state,

2 the DC high-speed switch Fig. 1 in a partial section, in the switched on state,

Fig. 3 shows a variant of a DC high-speed switch with a contact bridge, which projects with part of a contact sheet in the direction between the contacts bridged with the line connected in parallel.

Fig. 4 viewed the DC high-speed switch Fig. 3 without a chimney from above and

Fig. 5 shows a variant of a DC high-speed switch with an electrically conductive lever in the line for the accelerated opening of a contact point.

1, two fixed contact blocks 1 are arranged symmetrically to a movable contact bridge 2. The contact blocks 1 each have a trapezoidal projection 3 with contact surfaces 4 on their mutually facing sides. The contact bridge 2 is provided on its side facing the trapezoidal projections 3 with beveled contact surfaces 5 which are adapted to the contact surfaces 4 of the projections 3. The contact bridge 2 is connected by means of a switching rod 6 to a switching device S-E, not known per se, which is known. On the fixed contact blocks 1 at the level of the contact bridge 2 contact sheets 7, 7 'made of copper are fastened by means of screws 8. The contact sheets 7, 7 'have the same shape as the projections 3 and are arranged at a small, everywhere the same distance from them. On the sides of the contact bridge 2 facing the contact blocks 1, contact sheets 9, 9 'are fastened by means of screws 8. The contact blades 9, 9 'extend parallel and at a short distance from the contact surfaces 5 of the contact bridge 2 further upwards. The contact sheets 7, 7 'and 9.9' are provided on the opposite, sloping surfaces with contact plates lia, 11 'a made of a silver-cadmium-oxide alloy with a high silver content. In the free spaces between the contact bridge 2 and the lower parts of the fixed contact blocks 1 8 insulating plates 12 are arranged at the level of the screws. The upper end faces of the fixed contact blocks 1 are covered by further insulating plates 12 '. Above it is an extinguishing chamber 13, which has a rectangular cross section and is designed as a chimney 15. In the quenching chamber 13 there are quenching plates 14, which are used to divide an arc that arises when switching on or off. A current path formed by an electrical connecting line 16 between the contact sheet 7 'and the movable contact bridge 2 emerges from the chimney 15, which is represented on the front side by a perspective-drawn side wall part 15a, and has corresponding crankings 16a for this purpose. The line 16 is connected to an overlying baffle plate 14.

The line 16 is made from individual straight copper bars and has corresponding galvanic connections; the movable contact bridge 2 is galvanically connected to a movable strand 17 made of copper by means of two strand attachments 10 formed by screws.

In the following figures, the same reference numerals are used for the same parts.

Fig. 2 shows the switch described above in a partial section in the closed state. The side wall part 15a is not shown, accordingly the spatial shape of the line 16 with its bends 16a is clearly visible. Their galvanic connections 18 are also shown.

FIG. 3 shows a DC high-speed switch of the same type as in FIGS. 1 and 2 but with a differently designed movable contact bridge 2 '. The contact sheet 9 lies in a form-fitting manner on a contact surface 5 'of the contact bridge 2', i.e. it cannot spring. In contrast, the contact sheet 9 'is spring-mounted and protrudes with its end part in the direction of the left contact surface 4, which is connected to one end of the line 16 as in FIGS. 1 and 2.

This extended contact sheet 9 'takes on the one hand the arc that arises during the switching function, supports commutation on the secondary path and allows it to run in the direction of the arcing chamber 13 in a targeted manner.

With the extinguishing chamber 13 removed, the width of the individual parts can be seen in the view from above according to FIG. 4. The bend 16a of the line 16 is clearly visible here. As a further variant of the examples described above, the line 16 'is shown here in broken lines, which is designed as a second two-layer blow coil.

The geometric routing of the line 16 can in principle be freely optimized with regard to a maximum blowing effect, since this is merely a secondary flow path, which is advantageously carried out predominantly outside the arc chamber. This line 16 can thus be experimentally adapted in its geometric shape to the respective switch. This shape is to be determined in such a way that the arc is driven into the quenching chamber 13 as quickly as possible. The high possible current density proves to be a particular advantage, since the line 16 only has to be dimensioned for the short time of the pulse-like contact separation and subsequent commutation of the arc.

When dimensioning the line 16, care must be taken that the resistance Rs is less than Au / î, where: Au = arc base voltage at the corresponding contact point IIa, IIb and î = maximum current with contact separation.

As a practical example, assume that the arc base voltage is Au = 25 volts and the current is î = 10 kA. This results in a resistance Rs of 2.5 m £ l, which corresponds to a copper line 16 with a cross section of 25 mm and a length of 3 m.

The function of the switch arrangement shown schematically in FIG. 5 essentially corresponds to the figures described above. The contact tablets are labeled A, A ', B, B'. Instead of fixed contact blocks, arcing horns 19 and 20 have been used; the power supplies and connection rails for the positive pole of a DC network are designated 21 and 22. An arc that jumps from the contact sheet 9 ′ to the arcing horn 20 is also designated by 30. The loop-shaped movable contact bridge 2 ″ has an impact point 24 for a stop 23 of a lever 16b movably mounted in a pivot point 25 in the line 16. In the area of one end side of the lever 16b, a return spring 26 with two travel limits is attached Contacts AB arranged quenching plates 14 '.

This arrangement works as follows:

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First, by actuating the switching rod 6, the contact bridge 2 "is moved, the contacts A, B of the left contact point opening. At the right contact point, the spring force in the contact sheet 9 'ensures that the contacts A', B 'are still closed The current i can initially flow through the arc 16c via the line 16. The current i flows in parallel and in the same direction as the current I in the connecting bar 22. This current I is then via a Wire 17 is transferred to a movable lever 16b, which is rotatably mounted about a pivot point 25. This lever 16b is pulled by the return spring 26 against the lower travel limit, so that when the switch is closed, its stop 23 is spaced apart from the impact point 24. The current is now drawn from the lever 16b via the strand 17 'and transferred to the contact bridge 2 ". It has hereby been achieved that, in addition to the blowing loop, line 16c has been created, through which the same current flows twice, once through lever 16b, in one and through contacts B ', A' through lever 16b parallel part of the connecting rail 22 in the other direction. The result of this is that these two 5 conductor tracks are repelled from one another and the lever 16b impulses with its stop 23 on the stop point 24, as a result of which the spring prestressing force in the contact sheet 9 'is overcome and the contacts A', B 'are opened quickly.

10 The quenching plates 14 'serve to support the quenching of the arc which arises when the left contact point is opened.

Of course, the individual variants can be constructively combined with one another; The considerations given in the example of a DC high-speed switch also apply to AC switches. In addition, the inductive line 16 or. the corresponding blow coil can also be equipped with an iron core for local strengthening of the magnetic field.

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2 sheets of drawings

Claims (10)

647 353 1. Electrical switch, in particular for direct current, with a switching chamber formed from at least two insulating material walls, in which a movable contact bridge is arranged, and with at least two fixed contacts arranged at a certain distance from one another, the contact surfaces of the fixed contacts and the movable contact bridge are attached at least approximately symmetrically to the axis of movement of the contact bridge and, in the switched-on state, the contact points between the two fixed contacts and the contact bridge are connected in series, characterized in that one (1 la, 1 lb; A, B) of the two contact points (1 la, IIb; 11 'a, 1 l'b; A, B, A ', B') is bridged by a line (16) connected in parallel and running outside the switching chamber, the resistance of which is greater than the contact resistance at the contact point (1 la, 1 lb; A, B). 2. Electrical switch according to claim 1, characterized in that the contact bridge (2 ', 2 ") during a switching operation with a contact sheet (9') in the direction of the contact point (lia, 1 lb.) Bridged with the line (16) connected in parallel ; A, B) protrudes between the fixed contacts (1 la, 1 l'a; A, A '). 2nd PATENT CLAIMS 3. Electrical switch according to claim 1, characterized in that the line (16) is designed in the form of a magnetic blow loop. 4. Electrical switch according to claim I, characterized in that the line (16) is designed as a single or multi-layer magnetic blow coil. 5. Electrical switch according to claim 1, characterized in that the line (16) is designed in the form of two laterally the contact zone and outside of the switching chamber and opposite magnetic blow coils connected in parallel. 6. Electrical switch according to claim 1, characterized in that the contact bridge (2) has an asymmetrical pressure suspension, which is higher in the area of a contact point (1 l'a, 1 l'b) than in the area of the other opposite contact point ( 1 la, 1 lb). 7. Electrical switch according to claim 2, characterized in that the contact sheet (9 ') is resilient. " 8. Electrical switch according to claim 1, characterized in that the contact bridge (2) is articulated and asymmetrically connected to a switching device (S-E). 9. An electrical switch according to claim 1, characterized in that the line (16) has a lever (16b) which is rotatably mounted about a pivot point (25) and which is provided with a stop (23) which has an impact point (24) on it Contact bridge (2) is assigned. 10. Electrical switch according to claim 1, characterized in that a pivotable movable lever (16b) is arranged on the side of a connecting rail (22), which is galvanically connected on the one hand to the line (16) and on the other hand to the contact bridge (2) and the outer pivotable end 'of which is provided with a stop (23) to which an impact point (24) on the contact bridge (2) is assigned.