DE19842058A1 - Fault current protection switch has auxiliary breaker with pre-tensioned contact springs or contacts under mechanical tension by e.g. compression springs, connected to melting fuse element - Google Patents

Abstract

The switch has auxiliary break points in the form either of separate units or integrated into the switch that irreversibly break the current feed lines within a defined time in the event of loss of the normal fault current protection function. The movable contacts (12) of the auxiliary break points consist either of pre-tensioned contact springs or of contacts set under mechanical tension by traction or compression springs and connected to at least one melting fuse element (11) that holds the contacts closed and burns through if protection functionality is lost.

Description

The invention relates to a residual current circuit breaker according to the preamble of Claim 1.

Residual current circuit breakers, such as. B. J. Feitknecht in the essay in the Electrotechnical Journal (ETZ), 1984, Issue 13, have been around for a long time known. These residual current circuit breakers have serious disadvantages: yours Failure rate is for a circuit breaker from which the life of Depends on people too big. This issue is discussed in detail in the article by D. Kieback in the magazine ELEKTRIE, Berlin 49 (1995) 4.

There has been no shortage of attempts to get this problem under control. So z. B. described in EP 0 502 393 B1 a residual current circuit breaker, the Test button pressed automatically without the power failing. This has the Advantage that the upcoming cold welding of the magnetic contacts is not up to leads to sticking these contacts because they open at regular intervals become.

But this invention also lowers the failure rate by a factor of 20 e.g. B. was already shown in the OKA study of the EBI, Gmunden, 1990.

Although this is progress, it can of course still happen that a residual current circuit breaker does not trip if there is a residual current, d. H. this measure improves the reliability and availability of the conventional devices many times over, but a residual risk remains.

DE 44 12 305 A1 describes a continuation of the idea of automatic Exam described. It consists in the fact that the test procedure is not just one Fault current of a certain size simulated, but that the test current slowly up to trigger the magnetic contacts rises. The tripping current is each saved and with the help of these saved values will be on the expected Failure (exceeding the limit e.g. 30 mA) extrapolated.

This process also harbors a residual risk, namely this automatic too Monitoring can fail.

In the German patent application DE 195 28 918.8 there is therefore an emergency stop addition switching device described that if the above automatic monitoring fail or the rear derailleur should jam, an irreversible one or only by a specialist reversible separation of the main power lines takes place. The separation points can be achieved by various means, which are described in the above Patent application have not been exhaustively disclosed.

The object of the invention is therefore an automatically monitoring error to create circuit breakers of the type described above, which is characterized by particularly advantageous separation points in the above Auxiliary switching device that either separately or integrated in the switch.

This object is achieved by the characterizing features of the Claims 1 to 11 solved.

The separation points according to the invention are all based on the known principle of Fast fuse, which in the event of an overcurrent or a short circuit burn, melt, evaporate, etc. within a few minutes

The movable contacts of the additional disconnection point are made of pre-stressed Contacts made with insulating threads, rods or similar with fuse  materials, e.g. B. wires are connected, which keep the contacts closed and in the event of a fault current if the fault current protection function of the switch fails burn out so that the moving contacts move away from the fixed contacts lift off and cut the separation point of the additional switching device. The Burning out of the fuse materials is achieved in that these behind the separation point via, for example, two transistor switches that are in one Monitoring electronics are included, automatically connected to the mains voltage be connected. It does not matter whether the transistors are included become unusable.

Another possibility is to carry out the idea of the invention therein, the separation points of the additional switching device from at least two electrical to produce conductive wires and use them at a low temperature to fuse melting metal, for example solder. About these The connection point is an electrically or chemically operated, pulse-like one Heating that melts the metal when needed. Then one moves Insulated tension spring, for example an electrical heating coil surrounds the contact point apart and thereby separates the power line. Conceivable the separation point must also be designed so that the fuse element explodes explosively as soon as it is connected to the mains voltage (also called wire explosion element).

According to the invention, the separation point of the additional switching device can also be made up of two produce electrically conductive thin metal plates, which with the solder z. B. to be connected at points. There is a compression spring between the plates arranged, which can be heated with the help of one or more heating plates or the like. Also here the separation point opens suddenly when the command from the monitoring separation unit has been issued. Heater, conductor and springs are one other isolated attached. Again, you can use an exothermic heating realize chemical compound.

From electrical engineering textbooks it is known that electric induction furnaces are used to melt metals. The secondary winding of a special transformer is formed by the conductive melting material together with the melting sump, which, embedded in an insulated, heat-resistant channel, surround the second leg of the transformer and thus form a turn. The current heat I ² R of the very high currents causes the melting.

This principle takes advantage of the invention in that the separation point of the Additional switching device consists of at least two wires, which again with z. B. Solder is connected and surrounded by a ring-shaped or metal-tubular part, that forms the secondary winding of the transformer and thereby in the event of a fault current if the fault current protection function of the switch fails, it acts as a heater that The connection point melts, a spring then strikes the wires pulls apart and thereby opens the separation point. Of course it is ring-shaped or tubular winding made of resistance material designed so that it gets very hot but does not melt itself.

In continuation of this idea, the separation point of the additive has now become switching device made of a ring of low melting metal, so that it itself forms the secondary winding of the transformer. They are closed on the ring separating power lines connected (soldered, welded) that they if necessary, be separated by an insulated spring in the ring melted state and thus the connection of the wires.  

Since the ring normally has to carry the load current, it is even better to use the ring to produce from electrically conductive material and at least two parts, the are soldered together.

If the ring is made of a highly conductive spring material, the insulated spring can be used no longer apply, because the ring opens automatically when the solder joint melts.

If you train the power leads resiliently and solder them together with the Ring parts together, so they lift when the joints melted automatically disconnect and thus disconnect the lines. Under irreversible understood that the fuse elements only from authorized specialists can be replaced so that the switch itself remains usable.

With reference to 9 figures, some of many conceivable exemplary embodiments of the Invention shown and explained in more detail.

It means in Fig. 1:
L and N the phase and zero lines of the power network, 1 a residual current circuit breaker, 2 the connecting lines to which a consumer is connected, 3 the transformer core of the switch, 4 a first winding to which the trigger 5 is connected and 6 a second one one which does not or only slightly loads the converter redundant and / or diverse unit, here a CMOS amplifier 7 is connected, 8 the switching mechanism which normally opens the contacts 9 in the event of a fault current, 10 an additional switching device consisting of the separation points 12 according to the invention , which are actuated when the contacts 9 do not open in the event of a fault current, and the control electronics 13 , in which, among other things, the voltage tapped behind the contacts 9 is measured and further processed.

In the event of a fault current, the control electronics 13 receives the signal "fault current is present" via line 14 . Then does the voltage measured behind the contacts 9 not within a prescribed time, e.g. B. not within 50 ms, towards zero, puts it over the fuse wire 11 by means of the transistor switch 19 mains voltage, which causes it to melt. As a result, the movable contacts 12 open because they are no longer held by the insulating threads or rods 15 and are lifted by the springs 12 a from the fixed contacts 12 b. The voltage fed into the electronics 13 also supplies the components contained therein with the necessary operating current.

Another disconnection point of an additional switching device is shown in FIGS. 2a and 2b. One recognizes the two sections of the power line 16 to be separated, which is separated by at least one solder joint 17 if it was melted by the heating winding 18 in the event of a fault current in the event of failure of the fault current protection function of the switch.

Analogously to FIG. 1, the heating is applied to the mains voltage by control electronics 13 with the aid of a transistor switch 19 . After the solder joint 17 has melted, an insulated spring 20 pulls the line 16 apart and thereby irreversibly disconnects the consumer from the power supply.

Fig. 2a shows the arrangement in the closed and Fig. 2b in the open state.

FIGS. 3a and 3b show separation points, the switching device also in an additional suitable in the fault current in case of failure the fault current of the switch protection function the current lines irreversibly separate. They each consist of two electrically conductive, thin metal plates 21 which are connected to at least one solder joint 17 . One or more heating plates 22 melt the solder joints 17 in the event of failure of the normal residual current protection function, whereupon the insulating springs 20 push apart the connection points and thereby separate the power lines 16 connected to the plates 21 . The portions of the power line 16 are fixed at 23 in FIG. 3b. If one surrounds the solder joint 17 with an exothermic, chemical connection instead of an electric heater and ignites it in the event of a fault current, the solder joint 17 melts suddenly and, as described, disconnects the lines 16 from one another.

Fig. 4 shows a heating principle, which is also well suited for the separation of the main power lines. The sections 16 of the power line are connected to one another, as in the other figures, by the solder joint 17 , which is located inside a secondary winding 24 of a transformer. The primary winding 25 of the transformer encloses the secondary winding 24 , which consists of only one turn, here of a very thin, rigid tube, sheet metal, grid, network, or the like, the heat of which serves as a heater.

The primary winding 25 has just enough turns that, for example, the sheet metal tube gets very hot, but does not melt itself. If the solder joint 17 has melted, the spring 20 pulls the sections of the line 16 apart and thereby disconnects the power supply from the consumer. In the control electronics 13 there is, for example, a relay or transistor switch 19 which connects the transformer to the power supply network L and N as required. 26 are air or other very thin insulation, e.g. B. very thin ceramic layers. If you want to equip a multi-pole switch with these separation points, you can pull several mutually insulated power lines 16 with several solder points 17 through the secondary winding.

A further development of this principle is shown in FIGS. 5a and 5b.

In Fig. 5a, the separation point of the additional switching device is made as a ring 27 made of low-melting metal, which forms the secondary winding of the transformer. The sections 16 of the power line to be separated are connected to the ring 27 , specifically via the electrically conductive, disk-shaped ring plate 28 . The insulating part 31 is fixedly connected to the iron core 30 of the transformer by means of a threaded pin 29 .

If the primary winding 25 is connected to the mains voltage by the control electronics 13 ( not shown here), the current flowing in the secondary winding consisting of the ring 27 induces such a large current due to the favorably chosen transmission ratio that the ring 27 suddenly melts and the Spring 20 opens the separation point. 32 represents another insulating part.

In Fig. 5b, the spring 20 has been arranged differently. The disk-shaped ring plate 28 of FIG. 5a was replaced by two rectilinear power supply lines 28 a, which connect the lines 16 to the ring 27 . All other numbers have the same meaning as in Fig. 5a.

In FIG. 6, the power contacts 32, in which the sections of the power lines are soldered 16, designed to be resilient, so that they automatically lift off from the electrically conductive ring 27, once it is melted.

Furthermore, the following are represented: 25 the primary winding, 30 the iron core of the transformer, 28 a the rectilinear power supply and 31 an insulating part.

Claims (13)

1. Residual current circuit breakers with additional disconnection points, which are either available as separate units or are integrated in the switch itself and which irreversibly disconnect the power supply lines within a specified time in the event of failure of the normal residual current protection function in the event of a residual current, characterized in that the movable contacts of the additional disconnection points either from prestressed contact springs or from contacts, which are put under tension by tension or compression springs, which are connected via insulating threads, rods, springs or the like to at least one fuse element, which keeps the contacts closed and which, in the event of a fault current, if the fault current protection function of the The switch burns out, so that the movable contacts or the contact springs stand out from the fixed contacts and irreversibly separate the separation points of the additional switching device. 2. Residual current circuit breaker according to claim 1, characterized in that the Fuse element behind the separation points via at least one (Transistor) switch of the electronic monitoring and control unit in the Residual current failure if the normal residual current protection function of the Switch is connected to the mains voltage and burns through, so that the contact springs or the movable contacts differ from the Lift off the fixed contacts and irreversibly separate the separation points. 3. Residual current circuit breaker according to claims 1 and 2, characterized records that the additional separation points from at least two electrically conductive Wires made with metals melting at low temperature, for example with solder, are connected to each other in the event of a fault current if the normal residual current protection function of the switch fails from one electrical heating are suddenly melted and that at least one insulated spring pulls the wires apart. 4. Residual current circuit breaker according to claim 1 and 3, characterized in that the electric heater consists of a heating coil, heating coil or the like, in or around which a helical tension spring is arranged, the the wires apart after the low melting metal has melted pulls. 5. Residual current circuit breaker according to claims 1 to 3, characterized records that the additional separation point from two electrically conductive thin Metal plates are made with a melting at low temperature Metal are preferably connected in a punctiform manner, between which an insulated Compression spring is arranged and provided with at least one heating plate are so that the separation point itself after melting the connecting material suddenly opens. 6. Residual current circuit breaker according to claims 1 to 5, characterized records that the power line, the heating coil and the tension spring from each other, for example, are arranged insulated by a ceramic coating.   7. Residual current circuit breaker according to claim 1 to 6, characterized in that the heater that burns out the fuse element or causes the solder joint to melt, from an exothermic, chemical Connection exists in a suitable manner around the element, or the Is soldered around or attached to the element and in Residual current case is ignited. 8. Residual current circuit breaker according to claim 1, characterized in that the Auxiliary disconnect consists of two wires, one with a low melting metal, e.g. B. solder, connected and from a ring, tube, lattice or net-shaped part is surrounded, which is the secondary winding of a Transformer forms and thus in the event of a fault current in the event of failure current protection function of the switch acts as a heater that the connection point melts and then a spring the connection point pulls apart and thereby opens the additional separation point. 9. Residual current circuit breaker according to claim 1, characterized in that the Additional separation point consists of a ring made of low-melting metal, which serves as the secondary winding of a transformer, the wires together connects and in the event of a fault current if the fault current protection function fails the switch separates them in that an insulated spring melted them in state and thus also the connection of the wires. 10. Residual current circuit breaker according to claim 9, characterized in that the Ring made of electrically good conductive material and made of at least two parts exists, which are connected to each other by a low melting metal are. 11. Residual current circuit breaker according to claim 10, characterized in that the ring made of electrically conductive spring material and at least two Parts consist of one another through a low melting metal are connected so that in the event of a fault current the fault current will fail protective function of the switch, the connection points suddenly open, the Ring parts separate by their own spring action and thereby the current-conducting wires are interrupted. 12. Residual current circuit breaker according to claims 9 to 11, characterized records that the additional separation point from a ring of low melting Metal exists, which serves as a secondary winding of a transformer connects resilient wires to each other and they in case of fault current at Ver tell the fault current protection function of the switch by separating them stand out from the molten metal and thereby the Open additional separation point. 13. Residual current circuit breaker according to claims 1 to 12, characterized characterized in that the fuse separating element from a Wire explosion element exists.