EP0002685B1 - Fluid-blast circuit breaker - Google Patents

Description

The invention relates to a gas pressure switch with a movable switching element arranged in a gas-filled switching chamber and a counter-switching element which is spring-loaded in the switching-off direction and which follows the moving switching element at the start of the switching-off movement, and in which the interior of the switching chamber is divided by a wall whose central opening is penetrated by the moving switching element and also contains a second movable wall, by means of which the movement following the switch-off movement compresses the gas located between the movable and the standing wall.

Such a pressure gas switch is known from FIGS. 4 and 5 of US Pat. No. 3,985,988. In this case, the movable contact piece carries a movable wall connected to it, through which the gas located between the movable wall and the standing wall is compressed during the opening movement. The resulting gas flow blows the arc between the contacts and facilitates its interruption. In this case, the force exerted by the drive, by which the switch-off movement is brought about, must additionally apply the force required to compress the gas. The drive must therefore be dimensioned both for triggering the movement and for compressing the gas.

Furthermore, it is known from DE-OS 23 49 246 to start the extinguishing gas flow in a compressed gas switch by means of an auxiliary arc drawn in the course of the switch-off action. This blows the arc drawn between the movable contact and the counter contact. The quenching gas flow therefore depends on the current to be switched off or the current flowing through the arc.

In another pressure gas switch described in US Pat. No. 2,280,321, the counter contact piece to the movable contact piece is spring-loaded in the switch-off direction and thus runs at the start of the switch-off movement of the movable contact piece until a piston located on the counter contact piece comes to bear against the end wall of the cylinder surrounding it . This end wall, however, separates the cylinder from the actual switching chamber, so that no gas compression occurs in the latter when the counter-switching element runs after the movable switching element. The quenching of the arc is therefore not influenced by the movement of the piston connected to the counter switching element.

Another switch is described in FR-OS 22 85 700, the switching chamber of which is filled with sulfur hexafluoride. Here the one switching piece is designed to be stationary. The movable contact is spring-loaded in the switch-on direction by a spring in order to ensure the contact between arcing contacts lying parallel to the actual contacts in the switch-on position. The switch-off movement carried out by the drive of the switch takes place against the force of this spring, which is compressed during the switch-off movement. The movable contact piece carries a piston, which moves downward during the opening movement and compresses the gas contained in a cylinder surrounding the contact piece. This is pressed out through openings in the movable contact piece on its end face, so that it blows the arc formed between the contact pieces and drives it onto the special arcing contacts. Since there is also a coil surrounding the stationary contact, the arc is subject to a magnetic blowing in addition to the blowing effect of the compressed gas, so that its extinguishing is simplified. Here, too, the compression of the gas is brought about by the drive of the movable contact piece, which in addition to the switch-off movement has to do the compression work for the gas and the work for compressing the spring loading the contact piece.

The invention has for its object to provide a gas pressure switch of the type mentioned, in which the quenching gas flow is triggered regardless of the current and regardless of the drive of the switch.

According to the invention, this is achieved in that the movable wall consists of a piston which is spring-loaded in the switching-off direction and forms an end face of the switching chamber and which carries the counter-switching piece. The movement of this piston is caused by the spring load alone when the counterpressure of the movable contact piece in the switched-on position is eliminated, the spring also performing the work required for compressing the gas located between the piston and the standing wall in the switching chamber. The drive of the movable contact is relieved of this compression work. In addition, since the movable wall forms an end face of the switching chamber, the spring does not lie in the gas-filled space of the switching chamber, so that its dimensioning corresponding to the total work to be performed does not pose any difficulties.

It is advantageous in the case of the pressure gas switch according to the invention to surround the counter switching element with a first coil through which the breaking current flows after the galvanic separation from the movable switching element another coil driven by the movable switching element and through which the breaking current flows is connected in the opposite direction. As a result, a magnetic field for blowing the arc can be developed favorably, so that the quenching conditions and thus the .cutting conditions of high currents are favored. The provision of two such coils around both contact pieces of a switch is known per se from US Pat. No. 3,858,015 and DE-PS 646,031. There is also described the possibility of forming such a coil from a spirally slotted hollow cylindrical part of the switching element.

Exemplary embodiments of the invention are described with reference to the drawing and the mode of operation is explained.

In Fig. 1, a gas pressure switch according to the invention is shown schematically in section.

Fig. 2 shows schematically a second embodiment of a gas pressure switch according to the invention in a sectional view.

The compressed gas switch shown in Fig. 1 has a hollow cylindrical, for example made of porcelain switching chamber 1, in the interior 2 is filled as a gaseous extinguishing and insulating agent, sulfur hexafluoride. A movable contact piece 3 is provided centrally in the interior, which interacts with a counter contact piece 4. The counter switching element 4 is electrically connected to a terminal 6 via a current band 5. The connection 6 is seated on a cap 7 which closes the switching chamber 1 at the end. The cap 7 has a tubular support 8 directed into the interior 2, which consists at least partially of insulating material and holds a wall 9 dividing the switching chamber 1. The wall 9 in turn carries a nozzle 10 which comprises the movable contact piece 3 in the switched-on position.

The carrier 8 is partially designed as a cylinder, in which a piston 11 is guided to move back and forth. The piston is loaded in the switch-off direction by springs 12 which are supported against the cap 7. The piston carries the counter-switching piece 4, which assumes the position shown on the right of the center line 13 in the switch-on position and the position shown on the left of the center line 13 in the switch-off position.

If the movable contact piece 3 is moved into the switch-off position in the direction of arrow 14 due to a switch-off command, the counter-contact piece 4 and the spring-loaded piston 11 follow the movable contact piece 3 a certain distance. The gas located between the end face 15 of the piston 11 and the wall 9 is pre-compressed until the electrical isolation between the switching elements 3, 4 takes place. The arc drawn is flushed and cooled by the compressed gas. The contact piece 3 is pulled further down in the course of the switch-off movement until it leaves the nozzle 10, so that the arc burning in the space between the piston 11 and the wall 9, as a result of the pressure increase caused by the burning arc, a quenching gas flow through the nozzle 10 in Gear sets.

In the embodiment shown in Fig. 2, in which the same parts are provided with the same reference numerals, the counter-switching element 4 is surrounded by a coil 16, which is flowed through by the counter-switching element 4 after the electrical isolation of the movable switching element 3 and a magnetic field for additional Blowing the arc results. The switching piece 3 is slotted in the region of its free end 3a in a cylindrical helix, so that it forms a second coil which is separated from the switch-off current, i. H. from the arc current. This second coil 17 is connected to the first coil 16.

As can be seen, the first coil 16 is formed by a spirally slotted hollow cylinder, which consists of electrically conductive material and is rigidly connected to the piston 11. The coil 17 is formed by a spirally slotted hollow cylindrical part of the movable contact piece 3. A ferromagnetic body 18 is arranged in the interior of the hollow cylindrical part of the movable contact piece 3, which contributes to an amplification of the magnetic field. The end faces 19, 20 of the coils 16, 17 carry erosion electrodes 21, which ensure high wear resistance under arcing stress.

The embodiment of the compressed gas switch according to the invention is particularly suitable for high interruption voltages and with low driving forces. It combines the advantages of pressure gas switches with current-dependent and current-independent extinguishing gas flow.

Claims (7)

1. Gas-blast contact breaker including a movable contact member (3) which is arranged in a gas-filled switching chamber (1) and a counter-contact member (4) which is springloaded in the break direction and which at the commencement of the breaking movement of the moving contact member (3) follows the latter, and wherein the interior (2) of the switching chamber (1) is divided by a wall (9) whose centre opening is penetrated by the movable contact member (3), and furthermore contains a second movable wall by means of whose movement, which follows the breaking movement, the gas which is present between the movable and the stationary wall (9) is compressed, characterised in that the movable wall consists of a plunger (11) which is springloaded in the break direction, forms a front side of the switching chamber (1) and supports the counter-contact member (4).

2. Gas-blast contact breaker as claimed in Claim 1, characterised in that following the galvanic separation from the movable contact member (3) the .counter-contact member (4) is surrounded by a first coil (16) which carries the breaking current and to which a further coil (17) is inversely connected, this further coil being operated by the movable contact member (3) and carrying the breaking current.

3. Gas-blast contact breaker as claimed in Claim 1 or 2, characterised in that the first coil (16) is formed by a spirally slotted hollow cylinder which consists of electrically conductive material and is rigidly connected to the plunger ( 11 ).

4. Gas-blast contact breaker as claimed in one of Claims 1 to 3, characterised in that the second coil (17) is formed by a spirally slotted hollow-cylindrical component (3a) of the movable contact member (3).

5. Gas-blast contact breaker as claimed in Claim 4, characterised in that a ferromagnetic body (18) is arranged in the inside of the hollow-cylindrical component (3a) of the movable contact member (3).

6. Gas-blast contact breaker as claimed in one of Claims 1 to 5, characterised in that the front sides (19, 20) of the coils (16, 17) support consumption electrodes (21).

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