DE1192265B - Circuit breaker for telecommunication, especially telephone systems - Google Patents

Description

Circuit breakers for telecommunication systems, in particular telephone systems The invention relates to an automatic switch for telecommunications, in particular telephone systems.

The invention is based on the object of a Overcurrent responding circuit breaker with manually operated reset means to be provided in such a way that with a simple design as short as possible of the return means switching times that cannot be influenced can be achieved.

In telecommunications technology there were previously self-switches for self and Known manual release, in which the contact points of a main circuit over a movable contact bridge has been closed or opened. When a Overcurrent in the main circuit to be protected was, for example, by means of a Armature of a solenoid or a bimetal strip, consisting of a contact mechanism actuated from latch slides and locking levers, via which the contact bridge in the respective switch position has been moved. The manual release happened via an as Pushbutton and pull switch designed manual actuator, its movement in turn actuated the contact mechanism and so the contact bridge in the respective switch position brought. The manual control element marked the respective switch position. As in modern telecommunications technology, especially in telephone exchanges Particular attention must be paid to short tripping times for switches is the well-known one Circuit breaker can only be used to a limited extent, since this is caused by the overcurrent or hand-generated movement via a relatively complicated mechanism the contact point of the main circuit had to be transferred, which was a relative resulted in a long tripping time. There is also the fact that one of many individual elements existing switching mechanism is expensive to manufacture and also as a result of Manufacturing tolerances with an increasing number of individual elements are the uncertainty factors of the device rise.

The circuit breaker according to the invention is to avoid these disadvantages designed so that a switching bridge designed as an armature the moving part forms a magnetic circuit fed by a permanent magnet, in which the holding force of the permanent magnet is under the influence of a release system, and that one of the designed as an armature switching bridge associated pole element of the magnetic circuit relative to the switching bridge can be moved so that the switching bridge after tripping with With the help of the permanent magnet, it is returned to its operating position by hand. Of the so designed self-switch has the advantage that if an overcurrent occurs the switching bridge, which is designed as an armature, is caused by the waste movement directly without any involvement further switching elements interrupts a main circuit, which means that so very short tripping times can be achieved. Simultaneously there is a simplification the construction of the circuit breaker according to the invention achieved in that the pole element of the magnetic circuit itself, which in the not triggered state the switching bridge in its Holds the initial position, is used to reset the switching bridge, so none further switching elements are required.

According to a further embodiment of the invention, the switching bridge, the release system and the permanent magnet mounted on a pivot lever with which the contact position of the switching bridge by hand if the release system is not activated can be influenced. The ones that occur with the known automatic switches, by the multiplicity of the switching elements caused by the uncertainty factors embodiment of the self-switch according to the invention thereby significantly reduced, that the few switching elements required here on a centrally arranged Swivel levers are mounted. The usual conditions of manual release as well as the Self-triggering are fully fulfilled in a simple manner. An influence the electromagnetically initiated release by actuating the manual control element is thus prevented.

The pivot lever is expediently designed as an angle lever, one arm of which serves as a handle and the other arm as a storage for the Switching bridge is designed and in which the pivot lever is designed as a magnetic yoke serves for the permanent magnetic flux. As already mentioned, was it In known automatic switches with manual and self-triggering common, the manual control element to be designed as a pushbutton for resetting. To trigger the contact elements To enable by hand (manual release), the push button had to be off, for example be pulled up by hand in their depressed position. This actuation is through the design of the manual operating member as a pivotable lever arm facilitates. Since the pivot lever also acts as a magnetic yoke for the permanent magnetic flux serves, additional magnetic conductors for closing the magnetic circuit can be saved will.

According to a further development of the invention is supported in the fallen State the switching bridge with one end on a counter bearing, which acts as an alarm contact is trained. As it is known in the case of self-switches, when there is an interruption of the main circuit to be protected an alarm contact is actuated indirectly or its Circuit closed. In contrast to designs with known automatic switches this is achieved in the development of the invention in that the sloping Switching bridge actuates the alarm contact immediately and that the alarm contact simultaneously the movement of the falling jumper is limited.

It is useful to reduce the dropping motion of the switching bridge to accelerate and precisely define that the switching bridge in itself is known Way is under the influence of an armature return spring attached to a changeable Fastener is stored. The changeable fastening element of the The armature return spring can change the tripping time of the circuit breaker in a simple manner and the contact force of the switching bridge on the alarm contact can be set will.

According to another embodiment of the invention, the switching bridge designed as a display element for displaying the respective switch position. At acquaintances Self-switches became the respective switch position by the position of as a push button trained manual control member, so that at low lift height the pushbutton, an error with regard to the position of the pushbutton cannot be ruled out was. The inventive self switch now has the advantage that the respective switching position of the switching bridge, for example in a window in the housing becomes directly visible. A false indication due to the failure of an existing contact mechanism is excluded because the switching position of the switching bridge is indicated by itself will.

As already mentioned, form in the self-switch according to the invention the pivot lever and the switching bridge one influenced by a permanent magnet Magnetic circuit. In order to interrupt the magnetic circuit by moving the switching bridge, any trigger system can be used that, when a trigger pulse occurs the holding force of the permanent magnet weakens and so the triggering movement of the switching bridge enables. According to a further embodiment of the invention, this is when using an electromagnetically acting release system achieved in that the Pivot lever attached pole element serving to reset the switching bridge, Pole shoe-like design, the core of one of the holding force of the permanent magnet counteracting Forms electromagnets. This embodiment of the invention has the advantage that a such; - with magnetic release systems generally used electromagnet on the Pole element can be attached in a simple manner. Of course you can can also be achieved with an appropriate arrangement of the permanent magnet in the magnetic circuit, that the magnetic force of the permanent magnet is the magnetic force of the electromagnet so counteracts that the repulsive force of the two magnets in addition to the repulsion the switching bridge is used by the pole element. With appropriate dimensioning of the electromagnet can be dispensed with the armature return spring.

According to a development of the invention, the switching bridge is on her the end facing the pole element of the pivot lever also with a pole shoe-like end Approach provided that forms the core of an electromagnet, which is on the Pole element of the pivot lever counteracts attached electromagnet. The additional Electromagnet counteracts counter-magnetization, demagnetization or reversal of magnetization of the permanent magnet, which mainly occurs at higher currents, especially short-circuit currents. Furthermore, a particularly powerful repulsion of the switching bridge is achieved as a result. It is also achieved by the second electromagnet that the inductive resistance of the switch and prevents crosstalk between two neighboring switches will. The electromagnet assigned to the pole shoe-like approach of the switching bridge can also be designed as a plunger coil.

Taking advantage of the thermal release systems that occur According to another embodiment of the invention, there are advantages in the release system from a conductive piece located in the permanent magnetic circuit, which is made of magnetic Material, the magnetic resistance of which is temperature dependent, is formed over which the current to be protected is conducted in a manner known per se. At a such a trained trigger system comes in addition to the known advantage of high operational readiness caused by indirect heating of the guide piece added that, for example, in the case of high short-circuit currents, the present tripping system acting like an electromagnetic quick release, the easily movable one with a switching bridge with a small mass triggers so briefly that a large, heat generation that has a damaging effect on the permanent magnet when the one to be secured is opened Circuit is prevented.

According to a further development of the invention, a Fixed bracket used, one leg of which is used to support the switching bridge serves and its other leg with a manually adjustable, on the switching bridge acting pole element is provided. Since a release system is preferably on the fixed bracket is stored, so its power supply wires can be easily Way already laid before the installation of the moving parts of the circuit breaker will. In addition, the pole element to be operated by hand can be constructed to be easily movable because there are no other masses, such as power supply wires, is afflicted. The invention is illustrated with reference to in the drawing Embodiments described. It means F i g. 1 the schematically shown Circuit breaker according to the invention, FIG. 2 part of the circuit breaker with applied release system, F i g. 3 the part of the circuit breaker according to FIG. 2 in another embodiment, FIG. 4 the part of the circuit breaker according to FIG. 2 in a further embodiment, FIG. 5 another embodiment of the part the circuit breaker according to FIG. 2, fig. 6 shows part of the circuit breaker according to the invention in an embodiment that differs from the embodiments according to FIGS.

In Fig. 1, a switching bridge 4, preferably in the center of gravity, is mounted on an arm 1 of an angled pivot lever 2, which is rotatably mounted at a pivot point 3. The other arm 5 of the pivot lever 2 serves as a handle for actuating the pivot lever 2. In addition, a release system 7 controlled by a main circuit 6 to be protected is mounted on the arm 5, which in turn serves to control a permanent magnet 8 also attached to the arm 5, which is shown in FIG Figure is shown schematically. The two arms 1 and 5, the release system 7 with permanent magnet 8 and the switching bridge 4 form a magnetic circuit over which the permanent magnetic flux runs, the switching bridge 4 forming the movable part of this magnetic circuit. A contact spring 9 is attached to the switching bridge 4, which serves on the one hand to bridge the contact points 10 of the main circuit 6 and, on the other hand, when the switching bridge 4 is moved around its pivot point in the direction of the spring force of an armature return spring 12 mounted on a variable fastening element 11, alarm contacts 13 actuated.

The mode of operation of the automatic switch according to FIG. 1 is described below: In the figure, the circuit breaker is shown in its operating position, that is, the switching bridge 4 closes the main circuit 6 to be protected at the contact points 10 with its contact spring 9 the operating situation. When the switching bridge 4 is in contact, the magnetic circuit is closed with one of its legs on a pole element 14 of the release system 7, which is designed in the manner of a pole shoe. The holding force of the permanent magnet 8 is also dimensioned in the just mentioned position of the switching bridge 4 so that it outweighs the retraction force of the armature return spring 12. When an overcurrent occurs in the main circuit 6, the holding force of the permanent magnet 8 is now weakened by the triggering system 7 responding in a manner known per se. The switching bridge 4 opens the contact springs 10 of the main circuit 6 as a result of the now predominant retraction force of the armature return spring 12 and moves until it is supported on the alarm contact 13, which acts as a counter bearing and is thus actuated. In order to return the switching bridge 4 to its operating position again, the pivot lever 2 is pivoted with its arm 5 by hand in the direction of the arrow shown in the figure until the pole element 14 of the release system 7 has approached the fallen switching bridge 4 that the now fully effective magnetic force of the permanent magnet 8 brings the switching bridge 4 to the attraction. During this movement of the pivot lever 2, the alarm contact 13 of the switching bridge 4 serves as a fulcrum. Since the holding force of the permanent magnet 8 outweighs the retraction force of the armature return spring 12, the pivot lever 2 with the switching bridge 4 adhering to it can be returned to the operating position shown in the figure, the contact springs 10 of the main circuit 6 being closed again. If the trigger system 7 is not addressed, the switching bridge 4 can also be brought into its open position by hand by moving the pivot lever 2 in the direction of the arrow until the switching bridge 4 stops on the alarm contact 13. In order to precisely delimit these pivoting movements of the pivoting lever 2, stops, not shown, can be attached, for example, to its pivot point 3, which precisely define its extreme positions. In order to lock the switching bridge 4 in an intermediate position, in addition to the extreme positions, in which neither the contact springs 10 of the main circuit 6 are closed nor the alarm contact 13 is actuated, 2 latching points 15 are arranged on the housing of the automatic switch at the end of the arm 5 of the pivot lever . Each switching position of the switching bridge 4 is identified by a display element 16 which is attached to the switching bridge 4. Of course, it is also possible to use the triggering movement of the switching bridge 4 with the help of one or more additional actuators to automatically bring the pivot lever 2 out of its operating position into the open position, whereby an additional identification of the respective switching position of the switching bridge 4 is achieved.

In Fig. 2 is analogous to FIG. 1 of the switching bridge 4 on the arm 1 of the pivot lever 2 mounted. The permanent magnet 8 is attached to the other arm 5, on which in turn a release system, for example a so-called blocking magnet system, consisting of a cage 17 and one applied to a core 18 of the cage 17 Electromagnet 19 is attached. The magnetic circuit caused by the permanent magnet 8 is via a pole element 20 designed in the manner of a pole shoe and via the switching bridge 4 closed in the operating position of the automatic switch. When the electromagnet is excited 19 a resulting magnetic flux counteracts the permanent magnetic flux and thus causes the switching bridge 4 to fall off. The electromagnet acts in this structure 9 the permanent flux in its magnetic circuit regardless of the direction of magnetic flux contrary and can therefore with direct current in any direction of current or alternating current be fed.

In Fig. 3 is as in the description of FIG. 2, the switching bridge 4 is mounted on the pivot lever 2. On the arm 5 of the pivot lever 2, a pole element 21, which is designed in the manner of a pole shoe, is attached, which forms the core of an electromagnet 22 applied to it. In contrast to the exemplary embodiment according to FIG. 2, the permanent magnet 8 is attached to the switching bridge 4 and thus, in the operating position shown, closes the magnetic circuit via a pole shoe 23 attached to the permanent magnet 8. This means that when the electromagnet 22 is excited, the force generated by the armature return spring 12 (FIG. 1) and tearing off the switching bridge 4 is amplified by the mutual repulsion of the two magnets 8 and 22. In this way, the armature return spring 12 can also be saved.

In Fig. 4, the arm of the pivot lever 2 carrying the switching bridge 4 is designed as a permanent magnet 8, at the upper end of which a pole piece 24 serves to support the switching bridge 4. As in the embodiment according to FIG. 3, the other arm 5 of the pivot lever 2 is provided with a pole element 21 which is designed like a pole shoe and which forms the core of an electromagnet 25 . The switching bridge 4 is in turn provided at the end facing the pole element 21 of the pivoting lever 2 with a pole shoe-like extension 26, which likewise forms the core of an electromagnet 27. This additional electromagnet 27 is connected to the main circuit 6 to be protected (FIG. 1) in such a way that it counteracts the electromagnet 25 placed on the pole element 21 of the pivot lever 2, the electromagnet 25 acting in the same direction as the permanent magnet 8. In addition to the particularly powerful repulsion of the switching bridge 4 from its pole element 21, which occurs here, counter-magnetization, demagnetization or reversal of magnetization of the permanent magnet 8 by the electromagnet 27 is counteracted. The electromagnet 27 is expediently switched on as a bridge between the contacts bridging the main circuit 6 (FIG. 1). In this case, flexible current-carrying wires, which would influence the movement of the switching bridge 4, are avoided. In order to continue to effectively counteract counter-magnetization, demagnetization or reversal of magnetization of the permanent magnet 8, a magnetic shunt (not shown in the figure) can be arranged in the usual manner.

In the manner already mentioned, FIG. 5, the switching bridge 4 is mounted on the pivot lever 2. The permanent magnet 8, at the upper end of which a pole element 28 is arranged via a web 29, is attached to the arm 5 of the pivot lever 2, which is designed as a handle. Between the permanent magnet 8 and the pole element 28, a guide piece 30, which is designed in the form of a spirally bifilar or helically unifilar wound, magnetically conductive and insulated tape or wire, is inserted in such a way that it insulates from the adjacent parts 8 and 28 by disks 31 is. The guide piece 30 consists of a material with suitable induction-temperature characteristics. In the position of the switching bridge 4 shown in the figure, the magnetic circuit is closed. The guide piece 30 can also be designed in the form of a sheet metal punched out in a meandering shape or as a ferrite plate. The current to be protected flows directly through it, which means that when an overcurrent or a short-circuit current occurs, the conductive piece 30 is heated so that its magnetic resistance increases, which leads to a reduction in the magnetic flux in the magnetic circuit. In the case of a unifilarly wound guide piece 30, if the polarity is correct, an additional electromagnetic flux weakening is also effective. In certain areas of application of the self-switch, it is necessary to obtain tripping times that are independent of the room temperature. For this purpose, part of the release system 7 consists of a material with strongly temperature-dependent magnetic conductivity, for example a ferrite plate or a material known under the trade name Thermoflux, whereby a corresponding temperature compensation is achieved (not shown in the figure). Since the magnetic flux keeps the switching bridge 4 attracted in its operating position, when the holding force of the permanent magnet 8 is reduced, the counteracting force in the description of FIG. 1 mentioned restoring force, so that the switching bridge 4 is brought into its open position.

In Fig. 6 is the switching bridge 4, at one end of which is already mentioned Way, the permanent magnet 8 and the pole piece 23 are attached, on any leg 32 of a U-shaped bracket 33 is mounted. The other leg 34 of the bracket 33 forms the core of an electromagnet counteracting the magnetic flux of the permanent magnet 8 35 and serves with its extension of the flat contact of a hand in the direction of the arrow movable pole element 36, which in the operating position shown, the magnetic circuit closes.

To a full contact of the switching bridge 4 on their respective pole element 14, 20, 21, 28, 36, it is with self-switches according to the previous one Figure expedient, the pole element 14, 20, 21, 28, 36 with one or more in the Figures not shown, equip slightly movable pole pieces, so that inaccuracies of the contact surfaces on the switching bridge 4 and on their respective Pole shoe are automatically balanced.

Claims (10)

Claims: 1. Automatic switch for telecommunication systems, in particular telephone systems, d a d u r c h g e k e n n -z e i c h n e t that a switching bridge designed as an armature (4) the movable part of a magnetic circuit fed by a permanent magnet (8) forms, in which the holding force of the permanent magnet (8) under the influence of a Tripping system (7) is, and that one of the switching bridge designed as an armature (4) associated pole element (14; 20; 21; 28; 36) of the magnetic circuit relative to the switching bridge (4) can be moved so that the switching bridge (4) after tripping with the help of the Permanent magnet (8) is returned to its operating position by hand. 2. Auto switch according to claim 1, characterized in that the switching bridge (4), the release system (7) and the permanent magnet (8) are mounted on a pivot lever (2) with which the contact position of the switching bridge (4) can be influenced by hand (Fig. 1 to 5). 3. Automatic switch according to claim 2, characterized in that the pivot lever (2) is designed as an angle lever, one arm (5) serves as a handle and the other arm (1) is designed as a bearing for the switching bridge (4) and that the Swivel lever (2) serves as a magnetic yoke for the permanent magnetic flux (FIGS. 1 to 5). 4. Automatic switch according to claim 1 to 3, characterized in that that in the dropped state, the switching bridge (4) with one end on a counter bearing supported, which is designed as an alarm contact (13) (Fig. 1). 5. Circuit breaker according to the preceding claims, characterized in that the switching bridge (4) is in a manner known per se under the influence of an armature return spring (12) which is mounted on a variable fastening element (11) (F i g. 1). 6. Automatic switch according to claim 1 to 5, characterized in that that the switching bridge (4) as a display element (16) to display the respective switching position is formed (Fig. 1). 7. Automatic switch according to claim 1 to 6, characterized in that that the reset of the switching bridge (4) attached to the pivot lever (2) Serving pole element (21) formed like a pole shoe, the core of one of the holding force of the permanent magnet (8) counteracting electromagnet (22) (FIG. 3). B. Automatic switch according to Claims 1 to 7, characterized in that the switching bridge (4) also at its end facing the pole element (21) of the pivot lever (2) is provided with a pole shoe-like extension (26) which forms the core of an electromagnet (27) forms, which is attached to the pole element (21) of the pivot lever (2) Electromagnet (25) counteracts (F i g. 4). 9. circuit breaker according to claim 1, characterized in that the release system (7) consists of a permanent magnetic circuit lying guide piece (30) consists, which is made of magnetic material, its magnetic Resistance is temperature-dependent, is formed, over which in itself known Way the current to be protected is conducted (Fig. 5). 10. Self-switch according to claim 1, characterized in that a fixed bracket (33) is used for the magnetic circuit, one leg (32) of which serves to support the switching bridge (4) and the other leg (34) with a manually adjustable, on the switching bridge (4) acting pole element (36) is provided (Fig. 6). Documents considered: German Patent No. 761729; German explanatory documents No. 1116 733, 1018104.