CH662904A5 - HIGH VOLTAGE CIRCUIT BREAKERS. - Google Patents

Description

The invention relates to a high-voltage circuit breaker according to the preamble of claim 1.

A high-voltage circuit breaker that works according to the blower piston and not the two-pressure system has become known, for example, from DE-AS 1 913 969. In this arrangement, the blow piston or blow cylinder is moved together with the movable contact piece in the switch-off position, the drive not only having to be designed to actuate the inert masses, but also to generate the compressed gas.

A blow piston switch has become known (US Pat. No. 3,331,935), in which an additional piston is provided which is resiliently acted upon against the blow piston, this auxiliary piston being released during the switching-off process and thereby additionally compressing the compression space. With this arrangement, the drive can be made somewhat cheaper, since part of the compression is carried out by an additional auxiliary piston.

From DE-OS 2 618 087 it is known to design the drive of the circuit breaker electrodynamically in such a way that the short-circuit current flowing through a coil moves the switch into the open position.

From DE-OS 1 690 503 it has become known to provide an additional piston which acts in a manner similar to that of US Pat. No. 3,331,935, but in which the driving force (for the additional piston) comes from a coil arranged in the piston , which interacts with a fixedly mounted coil, in such a way that repulsive forces are generated which act on the additional piston for the additional composition of the extinguishing gas.

The object of the invention is therefore to provide a high-voltage circuit breaker of the type mentioned in the introduction, in which the drive energy is significantly reduced.

According to the invention, this object is achieved by the characterizing features of claim 1.

On the basis of the configuration according to the invention, the amount of energy for the gas compression for the arc blowing of currents above a defined value is generated by the electrodynamic effect of this short-circuit current, so that the drive only has to be designed for so-called powershift operations.

Both the short-circuit current and the rated current flow through the coil, so that commutations, such as those which have to be carried out in the case of the blow piston switch according to DE-OS 3 015 946, can be avoided. There, the coil itself is also designed to be resilient, so that it can contract and drive the additional blowing piston to blow the arc.

In addition, the additional piston preferably consists of a ring made of ferromagnetic material; it is conveniently slotted to avoid inductive circulating currents. The slot or slots is or are closed with casting resin for the purpose of gas sealing.

On the side opposite the piston crown surface, the additional piston preferably has a parabolic shape such that it has a small height on the inner radius and a large height on the outer radius. This parabolic shape serves to optimize the interfacial forces when the force components are reduced in the opposite direction of movement of the piston. The piston is returned via the tension spring.

The distances between the windings (winding heights) are expediently different in order to avoid inhomogeneities of the coil field on the magnetic body. In addition, a force increase on the piston in the direction of compression of the additional compression space can be brought about in that a fixed ring magnet is provided in the end region, by means of which bounce vibrations can also be absorbed.

Further advantageous embodiments of the invention can be found in the further dependent claims.

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The invention and further advantageous refinements and advantages of the invention are to be explained and described in more detail with reference to the drawing, in which an exemplary embodiment of the invention is shown:

The sole FIGURE shows a longitudinal section through a high-voltage circuit breaker designed according to the invention, the switched-on center line being shown on the left and the switch-off state on the right of the center line. In addition, two intermediate positions “contact separation” are dashed and the position “arc blown” in the extinguishing area is shown in dotted lines.

The high-voltage circuit breaker according to the invention has an arcing chamber tube 10, which is only shown in part and consists of insulating material. The upper end of the quench chamber tube is closed by a cover 12 which is cup-shaped and has a gas space 14 in which a holding element 16 for a cylinder spring 18 is arranged and suspended in a rotatable manner. On the inner wall of the cover 12, a cylindrical connection piece 22 is formed, into which a barrel cylinder 28 is inserted, so that the connection piece 22 partially engages around it. A magnetic coil 26 is wound around the cylinder 28, which consists of non-conductive, non-magnetic material, the turns of which are kept at a distance from one another by means of a winding support 24. The thickness of the magnetic coil 26 in the radial direction corresponds to the thickness of the socket 22. The thickness of the winding support 24 is also formed accordingly.

The magnet coil is electrically galvanically connected at 30 to the connector 22 and adjoins the connector 22 in the axial direction, so that the inside diameter and the outside diameter of the magnet coil and connector are the same.

An intermediate housing 32 made of electrically conductive material encloses the free end of the magnetic coil 26, the magnetic coil 26 being connected to this intermediate housing 32 in an electrically conductive manner at 33. The magnet coil 26 is thus located between the connecting piece 22 and the intermediate housing 32.

An insulating material cylinder 34 covers the bare magnetic coil from the outside.

The magnet coil 26 is thus located between the socket 22 and the intermediate housing 32, the current which is supplied to the circuit breaker at 114 via the cover 12 via the socket 22, the contact point 30, the magnet coil 26, the second contact point 33, flows to the intermediate housing 32.

The intermediate housing 32 surrounds a cylinder space 36. An inner tube 38 is attached to the end of the intermediate housing 32 adjacent to the coil, the inner tube 38 extending approximately to the height of the connecting piece 22. The inner tube 38 has at its end facing the housing 32 a radial flange 40, via which the inner tube is connected to the intermediate housing 32 such that its radially outer edge is inserted into a recess on the intermediate housing 32. As a result, the inner tube 38 forms a space with the Zylyinder 28 in which an additional piston 46 moves, so that the space 44 on the one hand through the piston surfaces of the additional piston 46 and on the other hand through a radially extending surface on the intermediate housing and the one flush with this radial surface radial flange 40 is limited to the inner tube 38. The additional piston 46 has on its side facing away from the piston surface 50 a parabolically shaped surface 48 such that the ring-shaped piston has a small height on its inside diameter (seen in the axial direction of the high-voltage circuit breaker) and one on its outside diameter compared to the height on the inside diameter has a large height, as a result of which a large outer surface is formed with which the piston is guided inside the cylinder 28 with the interposition of seals 52. On the inside diameter, namely on the surface 48, the piston has formations 54 in which the other end of the spring 18 is suspended.

The space 44 is first connected to the space 36 by means of channels 56 running axially in the intermediate housing 32 and then radially inwards towards the space 36. The space 14 is connected to the space inside the quench chamber tube 10 by means of channels 20 arranged in the connection flange or connection flange 12.

The contact system consists of a fixed contact piece 60, which is designed as a contact tulip arrangement, and a movable contact piece 62, designed as a switching pin, which is shown in the switched-on position to the left of the center line and is moved in the direction of arrow A by a drive (not shown in the drawing) in the switching-off direction .

At the free end of the intermediate housing 32, a cylindrical projection 66 is formed, in which a contact ring 64 is inserted. This contact ring 64 carries the fixed contact piece 60 inserted in a groove 65. At a distance from the fixed contact piece 60, an insulating nozzle 68 is inserted into the projection 66, which projects beyond the fixed contact piece 60 at a distance and is directed radially inward, so that this results in this the constriction 70 of the insulating nozzle is formed.

When switching off, the movable switching pin is moved in the direction of arrow A and in position 72 it separates from the fixed contact piece 60; the separation position is shown in dashed lines, to the right of the central axis. The nozzle's throat 70 is still closed. With further movement, the movable switching pin 62 passes through the throat and reaches the so-called delete position at 74, which is represented by the dotted line to the right of the center line. With further movement, the movable switching pin reaches the switch-off position 76. The current transfer from the movable switching pin 62 to the mating contact 78 takes place via an advantageous known roller contact system. However, this roller contact system is not shown, but is only symbolized by contact fingers at 78.

The intermediate housing 32 surrounds the space 36 in which the main piston 58 can move. On the inner surface of the inner tube 38, a shoulder 42 is formed, which serves as a stop for a compression spring 80, which rests with its other end against the back of the piston 58 and also tries to press it in the direction of arrow A. An axis pin 86 is connected to the main piston 58 via a stop ring 84 which engages in the main piston 58 and which has a first region 88 in one direction, namely counter to the switch-off direction, which ends in an end limiting ring 100, whereas in the direction towards the movable switching pin Axle pin 86 has an area 102 made of insulating material. This isolating area precludes parallel current paths from the main current path.

In the event of a switch-off, when the movable contact pin or switching pin 62 moves in the direction of arrow A, the axle pin 86 of the main piston 58 also moves in the direction of arrow A due to the force of the spring 80, the gas from the compression space 36 via overflow bores 104 in the contact ring 64 to the insulating nozzle 70. With the start of the contact separation at position 72 and with the occurrence of an arc between the fixed contact piece 60 and the movable contact piece 62, after passing over the insulating nozzle mouth, that is at 70, the gas flow for arc extinguishing becomes effective, namely into the extinguishing position 74 of the switching pin 62. During the switch-on process the main piston 58 is guided with the movable switching pin 62 via the axle pin area 102 and its stop ring 84 against the tension of the spring 80 into the starting position drawn to the left of the center line.

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The contact ring 64 has a guide ring 106 for guiding the insulating section 102 of the axle pin 86.

On its outer surface, the main piston 58 has a seal 59, which at the same time also serves for guiding or for better sliding of the main piston in the space 36.

Shield electrodes 108 are additionally provided on the outer surface of the intermediate housing 32. Similarly, the mating contact area also has 110 shielding electrodes 110.

In the normal case, therefore, when the load is switched off, the magnetic field generated by the magnet coil 26 is not sufficient to move the additional piston 46 in the switch-off direction. Rather, the blowing of the arc by the main piston is sufficient, which is moved in the direction of arrow A under the pressure of the spring 80 during the switching-off process and thereby slides on the inner surface of the intermediate housing 32. The main piston is quasi released by the movable switching element 62.

In the event of short-circuit cutouts, however, the magnetic field in the coil 26 is so large that it also moves the additional piston in the direction of arrow A. As a result, the space 44 below the piston is reduced and the compressed gas located there is reduced, so that this is caused by an open gas in this direction

Check valve 112 is pressed through channels 56 into space 36; the main piston is still in the starting position. As a result, in the case of short-circuit circuits, an additional quantity of extinguishing gas located in the space 44 s is supplied to the compression space 36 without consuming drive energy.

An extension 114 is formed on the upper side of the end flange 12 and serves to supply current to the end flange. As a result, the current will normally have the following path: contact connection 114, solenoid 26, intermediate housing 32, contact finger 60 - movable contact piece, or movable contact pin 62 - and mating contacts at 78. During the switch-off process, no communications will take place.

The switching chamber of the circuit breaker thus contains the contact system with the quenching device and the blowing system coupled in stroke, time coordination with the movable switching pin, which acts independently of the current load during the opening process. The additional compression system now works from a certain response current above the load current regardless of the switching pin movement.

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1 sheet of drawings

Claims (9)

662 904 1.High-voltage circuit breaker with a movable contact piece which can be driven by a drive, with a fixed contact piece, with a blowing piston-cylinder system which follows the movable contact piece for a predetermined distance during the switching-off process, with which the extinguishing gas in a gas-filled compression space is compressed, and from this to the arc when switching off is pressed towards its blowing, and with an additional piston-cylinder arrangement, with which, in the event of a switch-off, additional quenching gas for blowing the arc can be supplied to the latter, characterized in that the cylinder (28) of the additional piston-cylinder arrangement (46, 28, 38) is surrounded by a magnetic coil (26) which is switched into the current path and carries both the nominal current and the short-circuit current and which generates a magnetic field which is dimensioned such that it counteracts the force of a spring arrangement against the additional piston (46) (18) only drives in the event of a short circuit, u m to compress the additional extinguishing gas, and that the space (44) below the additional piston (46), in which the additional extinguishing gas is located, is connected to the compression space (36) of the blow piston cylinder system. 2. High-voltage circuit breaker according to claim 1, characterized in that the insert piston (46) is designed as an annular piston and consists of ferromagnetic material. 2nd PATENT CLAIMS 3. High-voltage circuit breaker according to claim 2, characterized in that the additional piston (46) is provided with slots for preventing inductive circulating currents. 4. High-voltage circuit breaker according to one of claims 2 and 3, characterized in that the surface of the auxiliary piston (46) opposite the piston surface (50) is parabolic, such that the height of the auxiliary piston (46) is small in the axial direction, which The height of the additional piston (46) on the outside diameter is large compared to that of the inside diameter, preferably 2 to 3 times as large. 5. High-voltage circuit breaker according to one of the preceding claims, characterized in that the spring arrangement (18) has a cylindrical tension spring, one end of which is fixed in place on the additional piston (46) and the other end of which. 6. High-voltage circuit breaker according to one of the preceding claims, characterized in that a ring magnet is provided in the end region of the compression path of the additional piston (46), which serves to amplify the force in the end region of the compression path of the additional piston (46) and to prevent bouncing processes. 7. High-voltage circuit breaker according to one of the preceding claims, characterized in that in order to avoid inhomogeneities in the magnetic field of the magnet coil (26), the coil turns are at different distances from one another. 8. High-voltage circuit breaker according to one of the preceding claims, characterized in that the magnetic coil (26) is wound onto a cylinder tube (28) and is held in place by means of spacers (24) of the winding or winding spacing. 9. High-voltage circuit breaker according to claim 8, characterized in that the magnetic coil (26) with the cylinder tube (28) and the spacers (24) forms a self-supporting connection from the connecting flange (12) to an intermediate housing (32).