DE1052499B - Metal extinguishing chamber for electrical switchgear - Google Patents

Description

GERMAN

The invention relates to metal arcing chambers for electrical switching devices.

The arcing chambers used in switches for electrical current are known to serve to deionization to accelerate the arc that occurs when the switch is opened, especially in the Moment when the current crosses the zero value. Two types of arcing chambers are known, and once chambers into which the arc is driven from the point of origin and towards one its extinction necessary length is drawn out, and on the other chambers, which just the other way around prevent the arc from escaping from the point of origin between the contacts, and where the space around the contacts is so narrow that around the contacts one on the arc acting strong deionization effect is developed. Pass the walls of this little one Space around the contacts made of insulating material, so there is only a small heat capacity and one poor thermal conductivity present. This creates the risk that the heated walls are made of insulating material represent an ionization source and z. B. with alternating current backfires after passage of current cause by the null value. To prevent this, the walls of the isolation chamber are often covered with sheet metal or made entirely of metal.

There are known switches in which the contacts of an equiaxed jacket from a current- and thermally conductive material are surrounded and in which in the cavity of the cylindrical body at least one of the two contacts is housed. It is also known that the sheath is made of magnetic material Material to be made in order to create a magnetic in it by permanent magnetism or electromagnets Generate field, depending on the design of the arcing chamber either to blow away the arc from the contacts or vice versa to fix the arc in the central zone is used between contacts.

The aim of the invention is to create an extinguishing chamber intended for low-voltage electrical switchgear of the kind in which the current-interrupting cylindrical contacts are equiaxed Sheath made of electrically and thermally conductive metal are surrounded, the arc in a certain Space is kept and the arc is extinguished in the metal chamber when the current passes through zero, So when the arc is in the glow discharge stage, it should be designed in such a way that that the dimensions of the residual body of the arc are reduced to the lowest possible level and the deionization become more intensive and faster

Metal extinguishing chamber
for electrical switchgear

Applicant:
CKD Modrany, närodni podnik,

Modrany, Prague,
Dr.-Ing. Bohuslav Novotny, Prague,
and Vladimir Ryb äf, Rudna
(Czechoslovakia)

Representative: Dipl.-Ing. A. Spreer, patent attorney,
Göttingen, Groner Str. 37

Dr.-Ing. Bohuslav Novotny, Prague,
and Vladimir Rybär, Rudnä (Czechoslovakia),
have been named as inventors

takes place than was previously possible, which again results in small dimensions for the arcing chamber. To solve this problem, according to the invention, the diameter is much larger than the roller-shaped contacts formed jacket at least one end to the interior of the Mantle turned so that a far into the jacket interior protruding hollow pin is formed in the at least one of the two working contacts protrudes with a gap that is of the order of magnitude after the mutual removal of the contacts is equal in the disconnected position. In this training when the contacts open under the influence of the forming arc, current of one contact via the jacket and the hollow pin to the other contact in the form of loops flow, which prevent the arc through electrodynamic action, from the point between the contacts to escape. There are various possibilities for carrying out this general idea: some of which are explained.

The arc is used to reduce or eliminate the contact burn caused by the arc expediently set in a rotational movement, which is arranged by permanent magnets or appropriately Electromagnet is brought about.

Compared to the known designs, the extinguishing chamber according to the invention differs basically in the fact that once the current flows through the metal jacket when the arc is formed

80Ϊ

and that, secondly, the arc is held in place by electrodynamic action will.

In the drawing, the invention is illustrated in exemplary embodiments in FIGS Section shown.

According to FIG. 1, the metal jacket of the quenching chamber is denoted by 1 , the edge end 2 of which is bent towards the interior of the chamber and surrounds the working contacts 3, 4 . Between the wall 2 of the chamber and the contact ends 3, 4 is the air gap, which is not larger in order than the distance between the separate contacts 3, 4, of which z. B. the contact 3 fixed, whereas the other contact 4 is movable in the direction of the arrow and is operated by the electromagnet or by hand, etc. Is created z. B. at the point 5 between the contacts 3, 4 an electric arc, he tries to get to the contact edge and to flare out at the point 6. In doing so, however, it strikes the inner wall of the jacket 2. Since this wall of the metal chamber is electrically conductively connected to the fixed contact 3 , part of the arc between the contact 3 and the wall 2 is extinguished and the current only flows away (shown thought in the drawing) to the contact 3 by the shell 2 and by the arc in the movable contact 4. the flow filaments thus form a current loop 7, which by its electrodynamic action back the arc between the contact 4 and the wall 2 to position 6 . The arc therefore remains in this position until the moment the current passes through the zero value, at which moment it is extinguished over a short length due to intensive deionization in a small room surrounded by cold walls made of a highly thermally conductive metal.

A further embodiment of the quenching chamber according to the invention is shown in FIG. 2, where both edges 2, 2 'of the jacket 1 of the metal chamber are bent over, the arc being formed between contact 3 and jacket part 2' as well as between contact 4 and jacket part 2 . The partial arcs are held in place 6 by the electrodynamic force action of the current loops 7, 7 ' , just as was the case in the exemplary embodiment according to FIG. 1.

According to FIG. 3, a further embodiment of the metal chamber is shown, the contact pin 8 being surrounded by a coil 9 through which the full switching current or part of it flows, which is achieved by series or parallel connection. The coil develops a magnetic field with lines of force 10. This field causes the arc to rotate around the switching contacts along a closed curve of its circumference, without the height of the continuous burning of the arc 6 being affected. It is also possible to provide both switching contacts 3, 4 with magnetizing coils.

According to the invention, the magnetizing coil can advantageously be replaced by a permanent magnet 11, as illustrated in FIG. 4, this magnet being inserted into the hollow switching pin 8 in the illustrated case in order to prevent it from being weakened by the magnetizing effect of the switched current. However, there is a difference between the arrangement with a permanent magnet and the same arrangement with a magnetizing coil, namely that the field 10 of the permanent magnet

nenten magnet 11 brings the arc in rotation in different directions in every half current period. This phenomenon of clockwise or counterclockwise rotation of the arc is, however, irrelevant with regard to the closed circumference of the contacts, as far as the extinction of the arc is concerned, which extinction always takes place when the switching current passes through the zero value at point 6 .

Another way of carrying out the invention with a permanent magnet 11 in the contact 3, the Fig. 5. In order to the power strength of the magnetic field at location 6 of rotation of the arc, which at the surface of the bent inwardly of the casing 1 edge 2 and the Contact 4 burns to increase, according to the invention, a ring 15 of magnetic material or even a permanent magnet of the same shape is arranged in the cavity between the bent edge 2 and the jacket 1 of the chamber. The position of the ring is chosen so that at the point 6 where the arc burns, the inclination of the magnetic lines of force 10 with respect to the axis of the contacts 3, 4 would be closest to 45 ° or would have this value.

The outer jacket 1 of the arcing chamber can advantageously be made of an electrically and magnetically highly conductive material, e.g. B. made of iron, and magnetize the magnet 15 radially or approximately radially. With this arrangement, the magnetic field at the point 6 is significantly increased.

A further improvement of the extinguishing chamber according to the invention, illustrating the Fig. 6. In order to make the direction of the magnetic field expedient and to increase its strength, one uses outside of the already-described permanent magnet 11 in the contact 3 or a further permanent, advantageously roller-shaped magnet 16 , which is arranged in the cavity of the other movable working contact 4 . This magnet is magnetized and positioned in such a way that the direction of its magnetic field is reversed with regard to the direction of the magnetic field of the magnet 11 . This arrangement produces a resulting magnetic field between the contacts 3, 4 with the course of the lines of force 17 according to FIG. 6. The arrangement described achieves a far better utilization of the magnetic field for extinguishing the switching arc.

The previously indicated variants of the constructive implementation of the inventive concept can be redesigned according to FIG. 7. The arrangement is based on a special design of the contacts 3 and 4, which each have a cavity 12 around the center of the contact, so that seating surfaces 13 arise in the shape of a circular ring. The resulting wall 14 at the contact ends narrows the current loop 7. The deformation of the current filaments then has an increased blow-out effect on the arc in the direction towards point 6, whereby the operational reliability of the arcing chamber is increased.

The arcing chamber according to the invention is particularly advantageous for switching off the alternating current; However, it also points to the corresponding voltage when the direct current is switched off the previous extinguishing chambers have significant advantages.

It is clear that the individual described and illustrated in the drawing are constructive

Claims (9)

Solutions of the quenching chamber according to the invention can expediently be combined in different ways without exceeding the scope of the inventive concept. Patent claims: 1. Metal arcing chamber for electrical switchgear, in which the current interrupting cylindrical contacts of an equiaxed jacket made of a current and heat conductive Metal are surrounded, characterized in that of the substantially larger in diameter than the cylindrical contacts formed jacket (1) at least one end to the interior of the jacket is turned in such a way that a hollow pin protruding far into the inside of the jacket is formed into which at least one of the two working contacts protrudes with a gap, wherein the gap between the contact (3,4) and the hollow pin (2) of the order of magnitude after the mutual removal of the contacts (3, 4) is in the disconnected position, so that when open the contacts under the influence of the forming arc current from the one contact (3) via the jacket (1) and the hollow pin (2 or 2 ') to the other contact (4) in the form of Loops (7 or 7 ') can flow, which prevent the arc through electrodynamic effects, to escape from the point (6) between the contacts (3, 4). 2. extinguishing chamber according to claim 1, characterized in that only one end of the jacket (1) turned inwards to form a hollow pin (2) and the other end of the jacket (1) is firmly, electrically conductively connected to the fixed disconnection contact (3), such that both contacts (3, 4) protrude into the hollow pin (2) (Fig. 1). 3. extinguishing chamber according to claim 1, characterized in that the jacket (1) with invagination is isolated at both ends to a hollow pin (2, 2 ') with respect to the contacts (3, 4), the two contacts (3, 4) are each in one of the hollow pins (2, 2 ') and the space between the two hollow pins (2, 2 ') are at the level of the contact point of the merged contacts (3, 4) is located (Fig. 2). 4. extinguishing chamber according to claim 1 and 2, characterized in that the fixed contact (3) designed as a bolt (8) and As is known, it is surrounded by an equiaxed magnetizing coil (9) which is either in Series with the working contacts (3, 4) or connected in parallel to the same (Fig. 3). 5. extinguishing chamber according to claim 2 or 3, characterized in that relative to the movable Contact (4) in a known manner coaxially with the same one permanent, for example cylindrical magnet (11) magnetized substantially in the axial direction is advantageous in a cavity (8) of the jacket (1), the end of which forms the contact (3) (Fig. 4). 6. extinguishing chamber according to claim 4 or 5, characterized in that in the space between the hollow pin (2) and the inner wall of the jacket (1) a ring (15) made of magnetic Material is provided in such a position that the direction of the magnetic lines of force (10) at the Point (6) of the arc with respect to the axis of the contacts (3, 4) is inclined advantageously by 45 ° and the magnetic field strength at the point (6) depending on the properties of the magnetic material it of the ring (15) is optimal (Fig. 5). 7. extinguishing chamber according to claim 6, characterized in that the ring (15) is a permanent magnet is. 8. extinguishing chamber according to claim 5, characterized in that also in a cavity of the Bolt-like movable working contact (4) a permanent magnet (16) in it is provided in such a way that the direction of its magnetic field (17) is reversed opposite to the direction of the magnetic field of the permanent magnet (11) in the fixed contact (3) is (Fig. 6). 9. extinguishing chamber according to one of claims 1 to 8, characterized in that the ends of the both contacts (3, 4) are provided with cavities in such a way that the contacts (3., 4) on the circumference of the end faces of the contacts z. B. place one on top of the other in the form of circular ring surfaces, and that the depth of the cavity in the contact (3 or 4) is such that the resulting wall (14) the current loop (7) narrows (Fig. 7). Considered publications: German Patent Specifications Nos. 496 330, 579 295, 496, 850771, 869,673; U.S. Patent Nos. 2,411,892, 2,411,893, 506,991. 1 sheet of drawings © 809 · 769/409 '3.59