DE2441561B2 - Gas switch - Google Patents

Description

The invention relates to a gas pressure switch according to m the preamble of claim 1.

Such a pressurized gas switch is particularly suitable for cut-off currents of 40 to 50 kA in high-voltage networks of over 100 kV provided.

In existing pressure gas switches which are movable v, Liehe hollow arc Knntaktstück disposed a stationary rod-shaped contact piece with respect to, and the movable main contact piece which is composed of several partial contact pieces and at the movable hollow arcing -, i> gen-contact piece is arranged around, both arranged in a chamber which is located upstream of the insulating material nozzle, which blows compressed gas from the blow cylinder including blow piston against the arc drawn when switching off. Because of this arrange- -, -, drying the stationary and the movable contact piece (including the movable hollow arc contact piece) is engaged are accommodated within the insulating material, which, however, an increase in the volume (or diameter) of the _h <> upstream portion of the insulating requires, so that the dead space in the insulating nozzle increases. As a result, the pressure of the compressed gas used to extinguish the arc drops noticeably when it reaches the arc, which t> 5 reduces the rated values of the breaking capacity or current.

In addition, since the opening diameter of the insulating nozzle is larger than the diameter of the stationary one Contact piece is chosen so that this the insulating material nozzle can reach through, a larger part of the compressed gas flows through the insulating nozzle to its downstream end, so that only a relatively small part of the pressurized gas in the opening of the movable hollow arc contact piece reaches, which is why the movement of the Arc on the inner wall of the movable hollow arcing contact piece and its cooling which further degrades the breaking capacity and current rating.

If the opening diameter of the insulating nozzle is large, part of the compressed gas flows through this opening without contributing to the extinguishing of the arc. Therefore, the blow cylinder and blow piston give off more compressed gas than would be necessary per se, which in turn increases the dimensions caused by the blow cylinder and blow piston, so opposes a compact design of the gas pressure switch.

Similar problems occur with known gas pressure switches on, namely one according to DE-GM 7 033 047, whose fixed arc contact piece however, it is not rod-shaped but hollow, and the rest in the downstream one Has the end face of the blowing cylinder compressed gas supply openings; and one according to GB-PS 1264756 accordingly the preamble of claim 1, in which the insulating nozzle expressly approximates Is arranged at right angles to the longitudinal axis of the gas switch, since its inner wall is parallel on the one hand and on the other hand it runs almost exactly at right angles to this longitudinal axis, so that the deletion of the Arc provided compressed compressed gas from an annular gap between the switch axis vertical section of the insulating material nozzle and the adjacent face of the thin-walled cylinder formed movable hollow arc contact piece exits radially against the arc.

It is therefore the object of the invention to further develop a gas pressure switch of the type mentioned at the outset so that that a more intensive and effective blowing of the arc is achieved by the flow of compressed gas will.

This problem is solved by the teaching according to the characterizing part of claim 1.

This training means that the arc is extinguished more intensively and cooling is more intensive of the movable, hollow arc contact piece than before (while largely avoiding dead space achieved in the compression chamber of the insulating material nozzle), so that the gas pressure switch is through higher Nominal values of breaking capacity and current.

Correspondingly, with unchanged nominal values of the breaking capacity and current, a more restricted one Construction of the pressurized gas switch possible because of the reduced consumption of pressurized gas, blowing cylinder and blow pistons can be made smaller.

Advantageous refinements of the invention are specified in the subclaims.

The invention is illustrated in greater detail, for example, with the aid of the drawing, which consists of a single figure explained, only the switching part of the gas pressure switch is shown.

An exemplary embodiment of the gas pressure switch is shown in its off position.

A stationary hollow main contact piece 21 consists of a plurality of electrically arranged cylindrically conductive parts and has on its end face springs 23, on the outer circumference of a screen 24 is provided to reduce the electric field strength.

The stationary, hollow main contact piece 21 has a movable, likewise hollow main contact piece 22 opposite.

In the middle of the fixed main contact piece

21 a stationary rod-shaped arc contact piece 25 is arranged, which is attached to a (not shown) immovable component is attached to which the stationary main contact piece 21 is also attached is. The fixed arc contact piece 25 is marked with ι ~> provided a front end part, which consists of arc-proof material.

On the other hand, a blowing device is arranged on the side of the movable contact piece, which from a blowing cylinder 26 and a blowing piston 27 are loaded stands. The movable main contact piece 22, which additionally serves to hold an insulating material nozzle 28, is arranged by screws 30 with the side wall 38 of the on the side of the contact piece Blowing cylinder 26 connected. The insulating material nozzle 28> > Is provided with an opening on its downstream side, the inner diameter of which is greater than the outer diameter of the fixed arc contact piece 25 and which is steadily expanding towards the outside. Inside the movable main contact piece j <>

22 a movable, hollow arc contact piece 31 is arranged; this is similar to how the movable arc contact piece 25 with a front end part made of arc-resistant material Mistake. r>

The blow cylinder 26 and the blow piston 27 delimit a blow chamber 32, which is an arc-extinguishing Contains compressed gas. In the side wall 38 of the blow cylinder 26 facing the contact side Compressed gas supply openings 33 arranged through which -in the extinguishing gas located in the glass chamber 32 against one between the fixed arc contact piece 25 and the movable arc contact piece 31 drawn arc is blown. Only a single compressed gas supply opening 33 is drawn, but four such pressurized gas supply openings of the same clear cross-section are in this one Embodiment available.

The insulating nozzle 28 is designed so that its upstream side, adjoining the insulating nozzle opening, the inner wall surface, i.e. its annular compression space, is flat and forms an angle θ of slightly more than 90 ° with the longitudinal axis of the switch . On the outside of the movable, hollow arc-> -, contact piece 31, a plate 34 made of insulating material controlling the flow of compressed gas is arranged and designed so that its top forms an angle α of just over 90 ° with the longitudinal axis of the switch. This plate _b o 34, which controls the flow of compressed gas, reduces the dead space in the compression space of the nozzle and prevents the arc from burning the extension of the movable main contact piece 22 or the screws 30. Since the movable arc contact piece 31 only serves a light _h> arc to ignite when the switch interrupts the circuit, and since the electric current when the switch is closed ii. \ Through the main contact

4->

-, n pieces 21 and 22 flows, the movable arc contact piece 31 is only small because it is traversed by current of great strength only during a very short Zettintervalls.

The insulating material nozzle 28 is preferably designed so that the distance L between its almost flat, upstream inner surface adjoining the nozzle opening and the side wall 38 of the blowing cylinder 26 is smaller than the radius R of its base surface. This reduces the dead space in their compression space through which the extinguishing compressed gas flows after it has flowed through the compressed gas supply openings and before it reaches an arc ignited between the arc contact pieces 25 and 31. The Isoiierstoffdüse 28 is designed so that its upstream side, adjoining its opening, almost flat inner surface and the top of the plate 34 controlling the compressed gas flow enclose between them a cross-sectional area which is perpendicular to the direction of flow of the compressed gas and essentially equal to the Sumrr ^. the cross-sectional areas of the four pressurized gas supply openings 33. The dead space in the insulating nozzle 28 is reduced even more.

Arranged in the middle of the blowing cylinder 26 and integrally connected to it is a tubular one Blow cylinder drive rod 36 on which the movable hollow arcing contact piece 31 is mounted. The device described above is arranged on a (not shown) pressurized gas container, which is filled with sulfur hexafluoride or other insulating, extinguishing compressed gas.

The mode of operation of the gas pressure switch described above will now be explained:

When the compressed gas switch is closed, i.e. the circuit is closed, the electrical current flows through the stationary main contact piece 21, the movable main contact piece 22 and the blowing cylinder 26. When the compressed gas switch is opened, i.e. the circuit is interrupted, the blowing cylinder drive rod is opened moved downwards (in the drawing) by an actuating device (not shown). As a result, the blowing cylinders 26, the insulating material nozzle 28, the movable main contact piece 22 and the movable arc contact piece are moved downward together and the main contact pieces 21 and 22 are separated. In this case, the electrical current flows on a current path given by the fixed arc contact piece 25, the movable arc contact piece 31 and the blow cylinder 26. Further downward movement of the blow cylinder drive rod 36 separates the arc contact pieces 25 and 3 \ and thereby creates an arc 35 between them.

On the other hand, this occurs in the blowing chamber 32 between the blowing cylinder 26 and the bias piston 27 trapped pressurized gas and blown through the pressurized gas supply openings 33 against the arc 35; it flows in two streams and two different directions, nänwich to the mouth of the movable one hollow arc contact piece 31 and to the opening of the insulating material nozzle 28. So the compressed gas blown out through the two outlets to the low-pressure part of the pressurized gas container. The arc 35 is extinguished by the compressed gas blown against it and thereby the electric Power interrupted.

In the switching part of the gas pressure switch are the

Main contact pieces 21 and 22 are arranged outside the insulating material nozzle 28 and only the arc contact pieces 25 and 31 are arranged inside the insulating material nozzle 28. The opening of the insulating material nozzle 28 can therefore have a diameter which is just large enough to accommodate the fixed arc contact piece 25 with a low current-carrying capacity. As a result, no more compressed gas passes through the insulating material nozzle than is necessary to extinguish the arc, and therefore the volume of the blow chamber 32 is sufficient to supply a substantial minimum amount of compressed gas.

The flat inner surface of the compression space of the insulating nozzle 28, which is on the upstream side of the isoliciMoiidüse ^{Düsenöff->:} · connects voltage, makes with the longitudinal axis of the gas blast switch an angle Θ of about 90 °. The upper side of the plate 34 controlling the compressed gas flow forms with the longitudinal axis of the compressed gas holder an angle α of just above SM) ". As a result of these '" features, the compressed gas flowing in through the compressed gas supply opening 33 can be at an obtuse angle to that between the arc contact pieces 25 and 31 drawn arc are blown and so a larger amount of compressed gas flows into the opening of the movable hollow arc contact piece 31 aN into the opening of the insulating material nozzle 28 , which is why the arc 3 drawn between the arc contact pieces 25 and 31 ! along the inner wall of the movable hollow arc-contact piece 31 in the same direction wan which can in which the compressed gas flows, so that the arc can be quickly cooled and safely extinguished.

Since the distance between the flat inner surface of the insulating material nozzle 28, which adjoins the nozzle opening on the upstream side of the insulating material nozzle, and the end face 38 of the blowing cylinder 26 is smaller than the radius of the base surface of the insulating material nozzle 28, the dead space on the flow path can be of the pressurized gas from the pressurized gas supply openings 33 to the arc drawn between the arcing contact pieces 25 and 31 is greatly reduced and a decrease in the pressure can occur; of the compressed gas can be prevented, which improves the switching effect of the switch. Preferably, the distance L between the flat inner surface of the insulating material nozzle 28 and the end surface of the blowing cylinder 26 should be at least about V, the inner radius R of the base surface of the insulating material nozzle, since with a small distance the clear cross-section of the flow path of the compressed gas is too small and the flow resistance for the Pressurized gas flow would be too great.

1 sheet of drawings

Claims (3)

Patent claims: 1. Compressed gas switch with a stationary, hollow main contact piece, one coaxial with it stationary rod-shaped arc contact piece and a movable blow cylinder, in to which a stationary piston is guided and which has a movable main contact piece, one to this coaxial movable arc contact piece and an insulating material nozzle upstream of the latter carries, which in the closed state of the gas pressure switch from the fixed arc contact piece is penetrated and has an annular compression space, characterized in that that the inner walls of the compression chamber are designed so that the main part of the compressed gas flow on the opening of the movable hollow arc contact piece (31) is directed. 2. Compressed gas switch according to claim 1, characterized in that both the strornabwärtsigc and the upstream (34) inner wall of the compression chamber an angle ( Θ, a) of over 90 ° with respect to the axis of the movable arc contact piece (31) towards its opening is inclined. 3. Compressed gas switch according to claim 1 or 2, characterized in that the distance (Z-) of the downstream inner wall of the compression chamber of the insulating material nozzle (28) from the end face (38) of the Blr.izylinders (26) is smaller than the inner radius (R) of the The base area of the insulating material nozzle (28) is.