EP0014393A1 - Pressurized gas high voltage power circuit breaker - Google Patents

Abstract

In a pressurised gas high voltage power circuit breaker with a switching contact arrangement (2, 3) which is located in an electrically negative compressed gas insulating/extinguishing atmosphere, particularly an SF6-atmosphere, an arrangement (5A, 5B) is provided for generating a magnetic field which acts on the switching arc in the sense of a better extinguishability of the arc as the current passes through zero. This arrangement (5A, 5B) for generating the magnetic field is designed, and/or limiting walls are provided, such that the arc, surrounded by the electrically negative compressed gas atmosphere, is essentially stationary and does not rotate. By means of a predetermined alignment of the magnetic field, the charge carrier paths are perturbed such that charge carriers are removed from the arc and are neutralised by the surrounding electrically negative compressed gas. <IMAGE>

Description

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

It is known to expose the switching arc to the influence of a magnetic field in high-voltage circuit breakers with a contact arrangement which are located in an electronegative compressed gas, usually SF ₆ atmosphere, as an insulating or extinguishing agent, in such a way that the arc rotates. The rotation is intended to extract energy from the arc so that it can be extinguished at the zero current crossing. In some versions, the rotating arc also serves to move the extinguishing agent or to generate pressure so that the extinguishing agent moved in this way blows the arc.

It is believed that the energy withdrawal of the rotating arc is practically effected solely by cooling the rotating arc relative to the compressed gas, ie to the SF ₆ gas.

Such switches with a rotating arc have a relatively complex contact arrangement, i.e. in addition to the switching contact pieces, they generally have additional ring contacts to which the arc passes when the switching contact pieces are pulled apart and along which they can rotate until extinguished.

The invention is based on the consideration that the energy withdrawal of the arc cannot, as is assumed, be brought about by the aforementioned cooling action of the arc due to the rotation relative to the compressed gas. At the moment of the zero current crossing, which is practically only interesting for the switch-off, the arc stands anyway, since the force acting on it is zero. Even if the arc previously rotated and would continue to rotate after the zero crossing, it is still in the current zero crossing since the direction of rotation changes after the zero crossing. At the crucial point (zero current crossing) or in the area in front (current goes towards zero and thus the torque also goes towards zero) there is no or only a slight relative movement, so that the cooling effect should remain low. If, on the other hand, the compressed gas rotated so that no great cooling effect was achieved during the entire current half-wave, the arc would "float" even in the zero crossing without relative speed, ie it would also rotate and would therefore not be cooled.

However, if, according to the knowledge of the invention, it is not the cooling of the arc by the relative movement between the arc and pressurized gas that makes the known switches functional, but practically only the depletion of charge strands in the arc, then there is also a rotation of the arc with the disadvantages of additional effort with regard to the special electrodes is unnecessary.

The invention is therefore based on the object of designing the compressed gas switch of the type mentioned in such a way that the same switching behavior can be achieved with less effort. This object is achieved according to the invention by the characterizing features of claim 1.

The compressed gas switch according to the invention therefore works with a switching arc standing in the magnetic field in the electronegative compressed gas atmosphere, in particular SF ₆ atmosphere. This arc is therefore in the space between two electrodes, the switching pieces of the switching path or additional contact pieces, which, however, do not have to be specially designed, in particular do not have to have a ring shape. They can therefore be designed similar to the usual pin or tube electrodes. The switch arc is therefore particularly simple - practically only the coils of the magnetic field arrangement are necessary - without changing the conventional one To influence contact systems favorably in terms of safe deletion. The teaching according to the invention is therefore advantageously also suitable for the additional retrofitting of conventional compressed gas switches, in particular SF ₆ switches.

The teaching according to the invention, which is the basis of all the embodiments described later in the drawing, is based on the fact that the magnetic field acts on the path of the individual charge carriers and not only on the arc as a whole. If the charge carriers take the known "corkscrew-like" paths, the thermal conductivity (the electrical conductivity inforge thermodynamic shock processes) is greatly reduced, so that the arc is extinguished even under severe subsequent stress. The arrangement of the field, the formation of the contact arrangement, etc. must therefore always be made such that the magnetic field swirls the path of the charge carriers in the arc in such a way that the conductance of the arc drops sharply. This effect is expressed by a higher operating voltage before the zero current crossing.

The magnetic field need not necessarily be perpendicular to the electric field of the arc. There is also no requirement for a homogeneous magnetic field; divergent fields or "cusp" fields are also conceivable. It is also possible to use a substantially parallel magnetic field (parallel to the electrical field), since it must be assumed that due to the thermodynamics, the charge carriers never run a straight path in the field direction, but that even the slightest path deviations due to shocks lead to transverse movements , which then result in full path deflection in the magnetic field.

The arrangement must be such that the arc as a whole cannot move out of the optimal position. This can be caused by chamber walls, for example in the form of a tube or certain magnetic field shapes or combinations of the two. Circuit breakers in the low-voltage and medium-voltage range with an arc in air that does not rotate in the magnetic field are known per se. In these known circuit breakers, the arc travels on rails into an arcing chamber, on the walls of which it is cooled (by heat dissipation). In the switch according to the invention, however, there is no cooling by heat conduction on corresponding walls; the focus is on depletion of load carriers.

Vacuum switches (in the medium-voltage range) with arcs in a magnetic field are also known, in which the effect of charge carrier depletion is exploited. Nevertheless, experts always use a rotating arc for the SF ₆ high-voltage switch, probably because of the firm conviction that cooling by the relative movement of the arc and the surrounding gas is crucial.

The invention is described in more detail with reference to exemplary embodiments shown in the drawing.

Show it:

senkrecht auf dem elektrischen Feld der Feldstärke

des Lichtbogens steht. Umleitstücke, d.h. Fingerkontakte 6a, 6b bzw. ein Isolierstück 7 im beweglichen Kontaktstück 3 sorgen für eine Umleitung des Stromes auf die Spulen 5a und 5b im geöffneten Zustand der Schaltstrecke. Ist die Schaltstrecke geschlossen, umgreifen die Fingerkontakte 6a, 6b das Schaltstück 2; der Strom fließt dann allein über die Kontaktstrecken 2, 3, d.h. die Spulen 5a, 5b sind kurzgeschlossen. Im dargestellten geöffneten Zustand fließt der Strom von dem Kontakt 2 über den Lichtbogen und die Spulen 5a, 5b zum Kontakt 3. Es ist weiterhin ein Rohr 8 vorgesehen, das den freien Raum zwischen den Schaltkontakten umhüllt und das den Lichtbogen in seiner Lage festhält, d.h., das Rohr sorgt dafür, daß sich .im Magnetfeld ein stehender Schaltlichtbogen ausbildet,The switching chamber of a compressed gas switch shown in Figure 1 has a housing 1, in which a fixed switching contact 2 and a movable switching contact 3 are inserted, and which contains an SF ₆ gas atmosphere in the usual manner. The switch contacts of the switch are in a position in which there is a light arch 4 is located between the switch contacts 2 and 3. Two coils 5a and 5b generating magnetic fields are also provided, in the embodiment according to FIG. 1 the magnetic field with induction

perpendicular to the electric field of the field strength

of the arc. Diverting pieces, ie finger contacts 6a, 6b or an insulating piece 7 in the movable contact piece 3 ensure that the current is redirected to the coils 5a and 5b when the switching path is open. If the switching path is closed, the finger contacts 6a, 6b encompass the switching element 2; the current then flows solely through the contact paths 2, 3, ie the coils 5a, 5b are short-circuited. In the open state shown, the current flows from contact 2 via the arc and coils 5a, 5b to contact 3. A tube 8 is also provided, which envelops the free space between the switching contacts and which holds the arc in place, ie , the tube ensures that a permanent switching arc forms in the magnetic field,

The magnetic field has a direct effect on the individual charge carriers of the arc, which describe the known corkscrew-like path, that is, emerge from the arc and are neutralized by the SF ₆ gas. Switches with a standing arc in the electrical field of an air atmosphere are known per se; in the present case, however, the atmosphere is an SF ₆ atmosphere, which has a particularly favorable effect on the neutralization of the detached charge carriers. The magnetic field swirls the path of the charge carriers very intensely, so that the conductance drops sharply. Because the magnetic field is perpendicular to the electric field of the arc, the turbulence is particularly intense because the force exerted by the magnetic field on the charge carriers is particularly large.

FIG. 2 shows an arrangement corresponding to FIG. 1, only switch contacts 2 and 3 being shown, and the direction of the magnetic field being indicated. In the exemplary embodiment according to FIG. 2, the magnetic field runs with induction parallel to the electric field. As already mentioned at the beginning, it must be assumed that due to the thermodynamics, the charge carriers never traverse a straight path in the field direction, but that even the slightest path deviations due to shocks lead to transverse movements, which then result in full path deflection in the magnetic field.

FIG. 3 shows the two switch contacts 2 and 3, between which the arc burns with the electric field, in accordance with the basic representation of FIG. 2. In this embodiment, the coils for generating the magnetic field are arranged such that a so-called "cusp" field is created, i.e. a magnetic field, the axially arriving field lines of which extend to the center of both sides of the switch arc.

FIG. 4 shows the switch contacts 2 and 3, between which the arc burns, in accordance with the basic representation of FIGS. 2 and 3. In this embodiment, a magnetic field is used which is bulged in the area of the arc, i.e. has a radial gradient, this magnetic field geometry ensuring that the arc is held directly by the magnetic field, so that the need to provide a chamber wall, e.g. in the form of a tube as in Figure 1 is omitted. This arc-holding tube would also have to be used in the arrangements according to FIGS. 2 and 3, but it has been omitted for reasons of clarity.

It is understandable that, because of the basic character of the invention, various other embodiments are available to the person skilled in the art or it is understandable that the figures can only show basic representations, i.e. the switches designed according to the invention also have blowing devices (not shown) and other auxiliary devices, as are customary in the case of compressed gas switches, in particular autopneumatic switches.

FIG. 5 shows an embodiment in which a conventional autopneumatic gas pressure switch for voltages up to 400 kV u.m. was subsequently provided with the features of the invention.

On the head of a cylinder 9 in which a piston 10 is slidably supported, i.e. The coils 5a, 5b are attached to a cylinder cover 11, on which there is also a nozzle 12 for blowing the arc when the piston 10 is moving in the direction of the cylinder cover 11, and in the one already explained in connection with FIG Way electrically connected to the contact piece 3, with the contact fingers 6a, 6b or its front contact finger 3a, which can be moved into the hollow, tubular contact piece 2. If the switch is opened, the switching arc is blown intensively; At the same time, the effect of the magnetic field on the arc causes depletion of charge carriers, which supports the arc's extinguishability.

It can be seen from FIG. 5 that the coils 5a, 5b can easily be attached to the nozzle of an SF ₆ switch which is present anyway, without the need for major modifications. Only the movable contact piece 3 must be provided with the insulating piece 7 at the top in a manner known per se.

For the sake of a better overview, measures for holding the arcs, e.g. a tube 8, not shown. FIG. 5 also shows only one of several possible embodiments of the arrangement of the coils 5a, 5b or the configuration of the connections for the coils. These connections should always be made in such a way that the current flows through the coils only when the contact path is switched off. The training depends on the contact arrangement of the switch in individual cases.

Claims (7)

1. Pressurized gas high-voltage circuit breaker with a switch contact arrangement, which is located in an electronegative pressurized gas isolating / extinguishing agent atmosphere, in particular SF ₆ atmosphere, and with an arrangement for generating a magnetic field that acts on the switching arc in the sense of better extinguishability of the arc in the current - acts at zero crossing,
characterized by h,
that the arrangement for generating the magnetic field is designed and / or boundary walls (8) are provided such that the arc (4) is essentially surrounded by the electronegative compressed gas atmosphere, and that the paths of the charge carriers by a predetermined orientation of the magnetic field are swirled in such a way that charge carriers are withdrawn from the arc and are neutralized by the surrounding electronegative compressed gas. 2. compressed gas high-voltage circuit breaker according to claim 1,
characterized by h,
that a pipe (8) concentrically surrounding the arc is provided as boundary walls. 3. compressed gas high-voltage circuit breaker according to claim 1,
characterized by h.
that the magnetic field, which is formed in the basic structure parallel to the electric field of the arc, has a radially directed gradient falling from the arc in the region of the arc for the purpose of holding the arc (FIG. 4). 4. compressed gas high-voltage circuit breaker according to claim 1 or 2,
characterized,
that the magnetic field is aligned substantially parallel to the electric field of the arc (Fig. 2). 5. compressed gas high-voltage circuit breaker according to claim 1 or 2,
characterized by h,
that the magnetic field is perpendicular to the electric field of the arc (Fig. 1). 6. compressed gas high-voltage circuit breaker according to claim 1 or 2,
characterized by h,
that the magnetic field is a "cusp" field (Fig. 3). 7. Pressurized gas high-voltage circuit breaker according to one of claims 1 to 6, which has a cylinder / piston arrangement (9, 10) with a cylinder cover (11) fitted on the switching path, to which a nozzle (12) for blowing the switching arc is attached,
characterized by h,
that the arrangements (5a, 5b) for generating the magnetic field in the region of the nozzle (12) are attached.

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