DE1132227B - Isolating and protective switches, in particular residual current circuit breakers - Google Patents

Description

Disconnectors and circuit breakers, in particular residual current circuit breakers There are circuit breakers for electrical systems and motors, in particular residual current circuit breakers, known, in which the switching elements mainly consist of a ring converter and a Contactor exist and in which these switching elements by special control elements actuated or triggered. Such known circuit breakers are in particular due to the use of the ring transducer, it is relatively expensive to construct due to the material and assembly costs, and it is very difficult if not constructional It is impossible at all to train them in such a way that their dimensions fit into the fit into the usual grid dimensions of control panels.

The inventor has set himself the task of eliminating these disadvantages so far to avoid known circuit breakers and to create a circuit breaker that extremely simple in its construction, material-saving and with small dimensions is.

To solve this problem, the inventor has a circuit breaker in the form of an electromagnetic contactor and the previously required Control elements saved in that he the individual components of the contactor in such a way trained and formed them to be the controls. By the invention thus become the control elements previously required for circuit breakers due to the special design of the switching elements, which are absolutely necessary anyway saved, and the two absolutely necessary switching elements, namely the Contactor and the ring transformer are combined into a single combined element.

According to the invention, a circuit breaker, in particular a residual current circuit breaker, characterized in that it is in the form of an electromagnetic contactor formed, consists of a magnetic yoke and an annular armature, in the contact bridges are arranged as a conductor for all alternating currents of the system to be protected. The magnet yoke is U- or C -shaped, and the armature is flatter rectangular or approximately rectangular ring formed, the interior of which with insulating material is lined and carries the resilient contact bridges.

The magnet yoke is expediently provided with coils for magnetization serve, the yoke is also magnetized by permanent magnets arranged on it or in it, it can also consist of permanent magnetic material. This is advantageous Yoke made of soft magnetic material with high coercive force, and the ring-shaped Anchor is wound from strip material, which advantageously has a high initial permeability Has.

According to a further development of the invention, the one facing the yoke Side of the armature by an insert made of diamagnetic material against the contact bridges shielded. Furthermore, a second ring can be placed around the actual anchor ring, which is magnetically shielded from the armature ring by a diamagnetic intermediate layer and is inductively connected to it by a piece of pipe made of a highly conductive material. A second ring made of soft magnetic material can also be attached to the yoke side of the anchor ring Material be attached, magnetically from this by a diamagnetic shield separated and inductively connected to it by a piece of pipe made of highly conductive material is. After further training, the two parts can be made of materials with different magnetic properties and produced using different amounts of material be. The anchor is advantageously equipped with five contact bridges, of which the first, third and fifth for the three phase conductors and the second and fourth used for the center conductor of a three-phase network divided into two tracks will. The insulating material for lining the inside of the anchor is expediently made of several nested parts, and the contact bridges can each with two and more turns must be passed through the interior of the armature.

The ends of the contact bridges with silver plating or silver rivets lie on mating contacts with the connection terminals when the armature is in the tightening position tied together are. In the drop position of the armature, the contact points are interrupted.

The effect of the switching device according to the invention as a residual current circuit breaker is based on the fact that the yoke magnetizes the armature in the on position keeps attracted and thereby closes the contacts, but that the magnetization is canceled and thereby the armature falls under the pressure of springs and the contacts are opened become, as soon as an alternating current of sufficient strength only one of the contact bridges flows through as a fault current (difference between the alternating currents). The magnetization of the Magnetic yoke can be done by permanent magnets built into the yoke or by magnetic coils, which are attached to the legs of the yoke, or by common use both means. In the case of magnetization by permanent magnets alone, the armature must go through the actuation of a handle can be moved into the switched-on position, while at the use of solenoids this expediently by means of a direct current pulse Pull the armature into the on position. The armature can then by holding magnetism (Remanence), by a weaker direct current flowing on or by the mentioned permanent magnets are kept in the on position. The required for this electrical switching elements and mechanical means are known.

A circuit breaker according to the invention has over the previous Switches have the following advantages: Extremely low expenditure on technical means, so in wages and materials; very simple and robust construction, therefore little space required and low susceptibility to failure; Insensitivity to rust and oily resin, to Lightning and mains voltage fluctuations; greatest reliability of electrical connections, because the strong wires are omitted, which otherwise act as the primary side in the ring converter between Terminals and switch contacts must be installed.

The formation of the magnet yoke and armature depends on the one hand the size of the response sensitivity, i.e. the fault current that triggers should lead (limit fault current), on the other hand according to the shock resistance, which is required by the switch. Embodiments of switches according to The invention are explained in more detail below with reference to the drawings. In the drawings Fig. 1 shows the front view of the switch with a U-shaped yoke and five contact tracks in an anchor of the simplest farm, omitting the connection terminals, Fig.2 a View of the same switch from above, Fig. 2 a corresponding to Fig. 2 View as a motor protection switch or overload protection switch, Fig. 3 is a view of the switch according to Figs. 1 and 2 from the side, Fig. 4 is an E-shaped Yoke with a coil and two permanent magnets, Fig. 5 an anchor for three contact tracks with inner and outer ring, Fig. 6 an anchor for three contact tracks with two superimposed Rings, Fig. 7 a view of a partial section of the anchor according to Fig. 1, with a Contact bridge that goes through the interior of the armature with three turns, Fig.8 die In Fig.7 built-in helical contact bridge pulled apart laterally and in isometric projection.

The U-shaped yoke 1 in Figure 1 is provided with two magnetic coils 11, which are traversed by a direct current, which becomes a one-time pulse-like Serve magnetization of the yoke 1 or also flow continuously with a lower strength can. The magnetization can be supported or maintained by the permanent magnet 10 will. The anchor 2 consists essentially of the anchor ring 2a, which is used to achieve a high response sensitivity from thin, soft magnetic tape with high Initial permeability is wound. Its interior is lined with insulating material 3, in which the contact bridges 5 carried by the springs 4 in the vertical direction lying movably. Their ends are provided with silver rivets 6 or silver plating, those in the on position of the switch against the contact pieces shown in Fig. 2 and 3 Press 7 on terminals 8. The supporting the falling of the anchor 2 Springs 9 can be provided with an adjustment device, e.g. B. in the form of Pressure screws in the crossbeam of the yoke 1, with which irregularities of the springs 9 or differences in the field strengths of the permanent magnets 10 can be compensated for. The insulating material 3 can be pressed or injected into the anchor ring 2a. But it can also consist of several parts that are nested inside one another.

In order to avoid undesired demagnetization, it is advisable in a three-phase network with a neutral conductor to divide its passage through the armature into two tracks, the contact pieces b and d of which are between two contact pieces of the three phase conductors a, c and e. Fig. 2 shows this arrangement in which the split center conductor is to be placed on the terminals 8 d and 8 f. This measure is superfluous in a network with pure three-phase operation. Three contact bridges, as shown in Figs. 5 and 6, are sufficient.

So that no demagnetization of the armature ring 2 a and thereby a reduced adhesion of the armature 2 to the yoke 1 due to strong multiphase alternating currents can occur even when the fault current is not flowing, it is advisable to use the the contact bridges 5 outgoing induction by attaching a strip 12 diamagnetic material against the side of the armature ring 2a lying against the yoke 1 shield. The magnetic shielding becomes even more effective if, as shown in Fig. 5 the anchor ring 2a lies in an outer ring 13, of which it is through a diamagnetic Shield 15 is separated. The actual network currents then rise within of the armature ring 2 a, as long as no fault current flows. The induction of a fault current from the anchor ring 2a to the outer ring 13 takes place essentially through a piece of pipe 14 made of a highly conductive material that goes through the insides of the rings 2 a and 13.

An even more effective magnetic shielding is achieved by an embodiment according to Fig. 6, in which the armature ring 2 a is attached under a second ring 16 made of soft magnetic material, magnetically separated from this by the shielding 18 and with it by the pipe section 17 made of highly conductive Material inductively connected. The versions according to Fig. 5 and 6 also give the possibility of making the two rings from soft iron materials with different magnetic properties and using differently large masses of material, such. B. the actual anchor ring 2a made of soft iron with high initial permeability and the ring 13 or 16 made of soft iron with high coercive field strength.

The E-shaped yoke 1 a shown in Fig. 4 can replace the U-shaped yoke 1 shown in Fig. 1 can be used. It is then expedient me with a magnetic coil 11 a, but equipped with two permanent magnets 10 a. That Soft iron used for yoke 1 or 1 a is used for the action of the switch be best if it has the highest possible coercive field strength.

To improve the responsiveness, the contact bridges 5 each with two or more turns, which are used as the primary lines of a converter through the inside of the anchor. An embodiment of a contact bridge with three turns is shown in Figs. 7 and 8. Fig. 7 shows the view a partial section of the anchor 2 according to Fig. l. The contact bridge 5 has the Form of a helix 19, which can be made from edgewise wound copper tape, but here with a view to simpler production from three stamped parts 20, 21 and 22, which are connected to one another by screws, rivets or welds are. The three turns are made inside the armature 2 by an insulating piece 23 guided and isolated from each other and against the spring 4. Fig. 8 shows the in Fig. 7 built-in helical contact bridge pulled apart laterally and in isometric Projection.

The switch housing not described and not shown, the for receiving the yoke 1, for guiding the armature 2 and for receiving the terminals 8, the operating handle, a testing device and other operating means Type serves, can be based on known constructions according to the desired Degree of protection and the desired installation and assembly options.

A switch according to the invention can also be used for the most diverse used for other purposes: Reference is made in particular to Fig. 2 a, namely, a switch according to the invention can then be used as a circuit breaker if according to Fig. 2 a with the solid lines of the phase conductor a is bridged at the ends protruding from the anchor ring 2 on both sides with the interposition of a suitable switch 25. When training as a motor protection switch is for the switch 25, for example, a thermal or electromagnetic Contactor used that bridges one of the contact bridges leading through the contact ring, so that the balance of the currents through the armature ring is disturbed.

If the switch according to the invention and according to Fig. 2a serve as overload protection, a thermal switch is arranged for switch 25, which consists, for example, of a bimetal strip between two switching contacts oscillates back and forth according to its heating or according to the passage of current.

Furthermore, a switch according to Fig. 2a can be used as an emergency switch train by adding a bridging resistor according to the dashed lines between the input of one current path to the output of another current path is switched. This bridging resistor 26 is expediently in series with a switch or switch-off button 25. The contact can also be made using the test button can be achieved at the residual current circuit breaker.

A switch according to the invention can be used as a limit switch of Fig. 2a in such a way that, also as with the emergency switch, a bridging resistor 26 is used with a switch 25 or a switch button. In this case however, the actuating button or the switch 25 is, for example, in the end position an elevator or a machine. When training as a motor protection switch the switch 25 connected in series with the resistor 26 can be controlled by a motor protection relay be operated. When training as a fault voltage circuit breaker, the contacting be made by a trip coil.

It can be seen without further ado that in these further embodiments when the switch 25 is actuated through the armature ring 2 or 2a, a differential current is generated flows, which cancels the magnetization of the armature ring and thus undershoots the armature drops under the pressure of springs and opens the contacts. A switching device according to the invention is therefore extraordinarily large with only very minor changes Scope and applicable to a wide variety of areas.

Claims (17)

PATENT CLAIMS: 1. Disconnectors and circuit breakers, in particular residual current circuit breakers, characterized in that it is in the form of an electromagnetic contactor formed from a magnetic yoke and an annular armature in which contact bridges are arranged as a conductor for all alternating currents of the system to be protected. 2. Isolating and circuit breaker according to claim 1, characterized in that the magnetic yoke Is U-shaped or E-shaped. 3. disconnector and circuit breaker according to claim 1 and 2, characterized in that the anchor as a flat, rectangular or approximately rectangular ring is formed, the interior of which is lined with insulating material is and carries the resilient contact bridges. 4. disconnector and circuit breaker according to claim 1 to 3, characterized in that the yoke (1) is provided with coils (11), which serve for magnetization. 5. disconnector and circuit breaker according to claim 1, characterized characterized in that the yoke (1) by permanent magnets attached to it or therein (10) is magnetized or consists of permanent magnetic material. 6. Separation and circuit breaker according to claim 1, characterized in that the yoke (1) is off soft magnetic material with high coercive force. 7. Separation and Circuit breaker according to Claim 1, characterized in that the ring-shaped armature (2) is wound from tape material. B. Isolating and circuit breaker according to claim 1 and 7, characterized in that the band material for the anchor (2) has a high Has initial permeability. 9. disconnector and circuit breaker according to claim 1, characterized characterized in that the yoke (1) facing side of the anchor (2) by an insert (12) made of diamagnetic material against the contact bridges (5) is shielded. 10. disconnector and circuit breaker according to claim 1, characterized in that that a second ring (13) is placed around the actual anchor ring (2a), which against the armature ring (2a) is magnetically shielded by a diamagnetic intermediate layer (15) and inductively connected to it by a pipe section (14) made of a highly conductive material is. 11. isolating and circuit breaker according to claim 1, characterized in that on the yoke side of the armature ring (2a) a second ring (16) made of soft magnetic material Material is attached, which is covered by a diamagnetic shield (18) magnetically separated and with it by a pipe section (17) made of highly conductive material is inductively connected. 12. Disconnector and circuit breaker according to claim 1 and 10 or 11, characterized in that the two rings (2 a and 13, 16) made of soft magnetic Substances with different magnetic properties and using different large amounts of material are made. 13. Disconnector and circuit breaker according to claim 1, characterized in that the armature (2) is equipped with five contact bridges (5) of which the first (a), third (c) and fifth (e) for the three phase conductors and the second (b) and fourth (d) for the split center conductor a three-phase network is used. 14. Disconnector and circuit breaker according to claim 1, characterized in that the insulating material (3) for lining the armature interior consists of several nested parts. 15. Disconnector and circuit breaker according to claim 1, characterized in that the contact bridges (5) each have two and lead more turns through the interior of the armature (2). 16. Disconnector and circuit breaker according to claim 1; characterized in that the two on opposite sides ends of a contact bridge protruding from the armature (for example a in Fig. 2a) must be bridged by a switch (25). 17. Disconnectors and circuit breakers according to claim 16, characterized in that the mutually opposite Sides protruding from the armature ends of the contact bridges of two different Current paths are connected to one another via a resistor (26) by means of a switch (25) connect are.