WO2007014816A1 - Short-circuiting device for use in low-voltage and medium-voltage systems for the protection of parts and personnel - Google Patents

Abstract

The invention relates to a short-circuiting device for use in low-voltage and medium-voltage systems for the protection of parts and personnel, comprising a switching element, which can be actuated by the tripping signal of a fault detection device, two mutually opposite contact electrodes having power supply means, wherein contact can be made with said contact electrodes at a circuit having connections at different potentials, furthermore the contact electrodes, under mechanical prestress, carry out a relative movement in relation to one another in the event of a short-circuit assisted by spring force, and a further part short-circuits the contact electrodes in a relative movement with respect to said contact electrodes, a sacrificial element as the spacer between the contact electrodes and having an electrical connection between the sacrificial element and the switching element, on the one hand, and one of the contact electrodes, on the other hand, in order to bring about thermal destruction of the sacrificial element in a targeted manner owing to current flow. In a first embodiment of the invention, the sacrificial element is a thin-walled hollow cylinder consisting of a high-melting metallic material. In a second embodiment of the invention, the sacrificial element is a wire or rod consisting of a conductive material having a low melting integral, wherein the sacrificial element is under mechanical prestress under tension in contrast to the first embodiment.

Description

 Short-circuiting device for use in low and medium voltage systems for property and personal protection

description

The invention relates to a further developed short-circuiting device for use in low and medium voltage systems for property and personal protection, comprising a switching element which is actuated by the trigger signal of a fault detection device, two opposing contact electrodes with means for supplying power, which to a circuit with terminals of different Potential are contactable, continue the contact electrodes under mechanical bias standing in the case of short circuit spring assisted perform a relative movement to each other, a sacrificial element as a spacer between the contact electrodes and with an electrical connection between the sacrificial element and the switching element on the one hand and one of the contact electrodes on the other hand, a current flow induced thermal destruction of the Targeting element to bring about specifically, according to the preamble of claim 1.

Furthermore, the invention relates to a method for initiating a short circuit in low and medium voltage installations with a short-circuiting device.

Various electrical faults can occur in electrical switchgear and distribution systems, which do not lead directly to the response or only to a delayed response of existing overcurrent protection devices. By way of example, arcing arcs may be mentioned here. Similar problems occur, in particular with regard to the protection of persons due to operational or error-related potential differences. Such errors can lead to extreme property damage, but also personal injury. To limit the damage in addition to a very quick detection of the error and its rapid shutdown is required.

Various solutions are state of the art for fast detection of various error cases.

Reference may be made here, for example, to DE 43 31 992 Al, which discloses a secured against arcs cell-like switchgear for the distribution of electrical energy. Also in DE 43 45 170 Al an arc fault Protective device for switchgear described, where there the actual switching or protective device is actuated by a signal from an AND operation of at least one photosensitive sensor and a light-insensitive sensor. The actual short-circuiter comprises a coil, wherein the short-circuiter generates a metallic short circuit between the parts to be short-circuited as a result of the forces which are produced by the induction current in cup-shaped metal parts under a vacuum. The energy storage source and the coil should be dimensioned so that the mentioned metallic short circuit takes place in a time between 0, 1 ms and 2 ms.

In a short-circuiter for use in systems for the distribution of electrical energy according to DE 197 46 815 Al a directly driven by a gas generator short-circuiting element is provided with a short-circuiting piston. The local short-circuiting piston should perform regardless of manufacturing tolerances optimal shock movement and at the same time be transport-secured.

Other typical short circuiters of the prior art are described, for example, in DE 94 19 141 U1, DE 197 46 815 A1 and DE 42 35 329 C2. Here, a distinction is made between reusable and single-acting devices. Reusable short circuiters are very expensive and expensive. In the case of single-acting short-circuiters, an explosive charge or a gas generator is generally used for assembling the electrodes, which understandably involves special protective measures during manufacture, transport and use.

According to DE 42 35 329 Al belongs to a short-circuit device to the prior art, which consists of at least one switching element which is actuated by a trigger signal of an error detection device. The short-circuiter provided there comprises at least two electrodes receiving the switching element between them and has current-carrying parts or regions. As a result of the current flowing directly in the current-carrying parts both in the switching element and in the short-circuiting device, min. at least one movable or deformable current-carrying region pressed against the electrodes and thus generates a metallic short circuit. In this known short-circuit device, the response times are insufficient and it is the overall design arrangement from a manufacturing point of view very expensive.

In the teaching according to patent DE 103 13 045 B3 a short-circuiting device for use in low and medium voltage systems is presented, which also includes a switching element which is actuated by a trigger signal of an error detection device. According to the local invention, the switching element is a triggerable overvoltage protection device, which can be brought to a response by a current or voltage pulse and destructible in the event of an error. At least one of the surge arrester receiving electrodes is under mechanical bias and is movable toward the opposite electrode, the overvoltage protector forming an electrode spacer which, in the event of destruction, allows the electrodes to contact the short circuit.

The aforementioned switching element may be a series circuit of a triggerable overvoltage protection device and a device with adjustable or defined melting integral. In this series connection, only the device with the defined melt integral can be destroyed in the event of a fault. In one embodiment, the aforementioned device is a glass tube fuse, a linear or non-linear resistor, a varistor, a low-melting metal or a metal alloy, a semiconductive or conductive ceramic, such a glass, or the like. To generate the mechanical bias and the relative electrode movement, a tension or compression spring is used according to DE 103 13 045 B3. Also, according to the related teaching of the prior art, an embodiment of the electrodes as a pot with a counter electrode is common, which has a plunging into the pot die.

However, as a result of further investigations, it has been shown that the execution and optimization of the sacrificial element is of great and extraordinary importance for the functional properties of the short-circuiter. comes. The basic aim of the optimization of a short-circuit device is to achieve the fastest possible closing movement of the main contacts and a very low load on the switching element, wherein the sacrificial element substantially influences these two parameters.

From the foregoing, it is therefore an object of the invention to provide an advanced short-circuiting device for use in low and medium voltage equipment for property and personal protection, said short-circuiting device should have a cost-effective to manufacture sacrificial element, which leads to a minimized loading of the switching element and the has the highest possible electrical conductivity to minimize the commutation with simultaneous high mechanical strength to use a high spring force with the aim of reducing the movement time.

The object of the invention is achieved with a short-circuiting device according to the combination of features according to claim 1 or 12, being additionally referred to an inventive method for initiating a short circuit in low-voltage systems using the short-circuiting device according to the invention.

In the short-circuiting device according to the invention according to the first embodiment of the invention for use in low and medium voltage systems for property and personal protection, this includes a switching element which can be actuated by the trigger signal of an error detection device. Furthermore, two opposing contact electrodes are provided with means for supplying power, wherein the contact electrodes can be contacted to a circuit with terminals of different potential.

Furthermore, the contact electrodes, under mechanical bias standing, spring-assisted in case of short circuit, a relative movement from each other.

The sacrificial element, which is provided as a spacer between the contact electrodes, is in electrical connection with the switching element on the one hand, and one of the contact electrodes, on the other hand, in order to purposefully bring about a thermal flow-induced thermal destruction.

According to the invention the sacrificial element is designed as a thin-walled hollow cylinder made of a refractory metallic material.

In one embodiment of the invention, it is possible to receive an electrically conductive substance in the hollow cylinder. The hollow cylinder is a structure of a pressure-resistant material, wherein the aforementioned filling is designed as a low-melting metal, for example. In order to avoid an excessively high melting integral value, instead of a partial filling, an insulating layer with low mechanical or even low temperature resistance can be arranged between the hollow cylinder and the actual conductive substance.

Upon the desired destruction of the sacrificial element, i. of the hollow cylinder, the substance located in the interior is released and can already realize an electrically conductive short circuit or support such a short circuit even before closing or complete contact without mechanical movement of the main contacts.

The hollow cylinder can be inserted and guided in recesses of the contact electrodes, so that a low contact resistance is given.

In a variant of the first embodiment of the invention, an insulating body and an auxiliary electrode is located in the stationary contact electrode, wherein the auxiliary electrode is in communication with the sacrificial element.

The opposing sides of the contact electrodes and the opposing surfaces may have a complementary conical shape with resulting centering effect in the case of short circuit contact.

Preferably, the ratio between the diameter and the wall thickness of the hollow cylinder is greater than 10: 1 selected. Defined structures or changes in wall thickness in the hollow cylinder can form current paths, with the result of uneven heating under current load and deformation with concomitant loss of mechanical strength. It remains in this case advantageously the conductive connection between the contact electrodes, but decreases the mechanical resistance of the hollow cylinder, so that under the action of the spring force of the short-circuiter can be quickly converted into a closed state.

A cavity can be formed between the contact electrodes in order to receive parts of the destroyed sacrificial element, without the desired low-resistance contact connection being impaired in the event of a short circuit.

Between the contact electrodes, a venting channel or a venting bore which is effective in the closed state can be effective in order to prevent forces arising due to an increase in pressure in the event of a short circuit, in particular during the creation of an arc, which counteract the closing movement of the contact electrodes.

The device for generating the biasing force can be designed as a compression spring, disc spring or the like spring arrangement.

According to the second embodiment of the invention, the sacrificial element is a wire or rod made of a low-melting-integral conductive material, the sacrificial element being in tension under mechanical bias.

In this embodiment of the invention, it is advantageous to provide labyrinthine, interlocking sealing elements between the contact electrodes in order to achieve movement support of the piston-like, movable contact elements in the case of arcing and pressure development.

In one embodiment of the second embodiment of the invention, the movable contact electrode can form a contact bridge between two electrical terminals. Again, the movable contact electrode can be designed as a displacement punch, which cooperates with a solid pot contact electrode, wherein in the pot contact electrode is a conductive, low-melting substance is located, which forms a complementary electrical bridge between the opposing contact portions when immersing the punch. In this case, therefore, the low-melting substance is forced out of the pot region of the corresponding electrode and enters the remaining gap of the opposing contact electrodes.

In the method for initiating a short circuit in low-voltage systems using the short-circuiting device according to the invention, a staggered connection of the short-circuiting device is assumed.

First of all, a brief activation of the switching element takes place after the detection of a fault. It is then a limitation of the short-circuit current through the switching element by means of sacrificial element and the impedance of the terminals achieved with a subsequent commutation of the current from the fault location to the short circuiter.

The short-circuit current is then interrupted by the switching element after a predetermined time and the system is again loaded with mains voltage.

In the case of sufficient reconsolidation of the defect, the supply of the plant is maintained. The short-circuiting device reports the error that has occurred and thus indicates a necessary check of the system.

However, if the fault persists, the switching element of the short-circuiter is again and permanently activated. The sacrificial element of the short-circuiter is overloaded in this case and there is the generation of a permanent metallic short circuit, which forces a shutdown of the system. The invention will be explained below with reference to exemplary embodiments and with the aid of figures.

Hereby show:

1 shows a first embodiment of the short-circuiting device with pressure-loaded movable contact electrode and hollow cylindrical sacrificial element.

2 shows an embodiment analogous to FIG. 1, but with a hollow-cylindrical sacrificial element which is at least partially filled with a conductive substance:

3 shows a first variant of the second embodiment of the invention with zugbelastastetem rod or wire as a spring element.

4 shows a second variant of the second embodiment of the invention with zugbelastastenem sacrificial element.

5 shows a third variant of the second embodiment of the invention with zugbelastastenem sacrificial element.

6 shows a fourth variant of the second embodiment of the invention with zugbelastastenem sacrificial element and a pot electrode having a conductive substance to be displaced, and

7 shows a block diagram for explaining the method for initiating a short circuit in low-voltage systems with staggered connection.

In the following embodiments, the same reference numerals are used for the same or equivalent elements.

According to the embodiments, the sacrificial element 5 has a special significance with respect to the effective operation of the short-circuiting device. The aim of optimizing the short-circuiting device is to achieve the fastest possible closing movement of the main contacts and a very low load on the switching element. The speed of the closing movement the main contacts in addition to the contact distance, the mass of the moving contact, the effective counter forces also determined substantially by the force-displacement curve of the spring 4 used. The higher the initial force in the tensioned state and the higher the residual force in the closed state of the short-circuiter, the shorter the closing time of the main contacts.

The mass of the moving contact and the spring force in the stressed state permanently act on the sacrificial element and require a certain mechanical strength.

On the other hand, the sacrificial element is to be overloaded as possible due to a low power supply and the desired movement of the corresponding main contact, i. cause the respective contact electrode. Until the current commutation of the fault current to the main contacts, the switching element is loaded with the fault current. The lower this load, the lower the cost of the switching element can be kept. In addition to the costs and the protection of the switching element is a rapid overload of the sacrificial element and a rapid reduction in the impedance of the Kurzschlusspfads serve, since after closing the main contacts a purely metallic short circuit is realized. Thus, the impedance of the switching element and possibly the existing impedance of the arc and the substantially ohmic resistance of the sacrificial element is eliminated from the fault circuit.

The sacrificial elements according to the invention have the following properties. There is a low melting integral (I ² t value) of the material to minimize stress on the switching element. The sacrificial elements have a high electrical conductivity to minimize the commutation time and have a high mechanical strength to use a high spring force in view of a desired reduction in the movement time of the contact electrodes. Furthermore, there is only a low arc voltage in the destruction of the sacrificial element for the realization of a short commutation time. Forces which counteract the mechanical movement, such. As a resulting increase in pressure are avoided or reduced. The destructive behavior of the in particular hollow cylindrical material is so specifies that there is no impairment of the mechanical movement of the contact electrodes.

As shown in FIGS. 1 and 2, the sacrificial element 5 is designed as a thin-walled hollow cylinder. As a material for the hollow cylinder are particularly suitable due to the high mechanical strength steels or iron alloys. Materials having high specific melting integral values, such as e.g. Copper or silver, lead with sufficient mechanical strength to a relatively higher load on the switching element.

The thin-walled hollow cylinder geometry is chosen so that the ratio of diameter to wall thickness is substantially greater than 10: 1. This geometry has a much higher mechanical strength compared to a solid cylinder of the same material at the same melt integral. This makes it possible to specify higher spring forces and ensures faster closing times of the contact electrodes.

Compared with solid material, the hollow cylinder according to the invention has a further advantage explained below, in particular at diameters of several millimeters.

As a result of low asymmetries in the current distribution on or in the hollow cylinder, the hollow cylinder heats and melts unevenly even at high current loads and short melting times. This effect can be deliberately promoted by the current transfer at the contact points or by a structuring of the cylinder. In principle, structural material influences or even the use of composite material are conceivable.

This uneven heating leads to small and medium current loads (melting times of a few minutes to a few milliseconds) to the deformation of the hollow cylinder. The hollow cylinder thus loses its mechanical strength in this process almost abruptly, causing the compression of the cylinder and the closing of the main contacts of the short-circuiter. This type of closing process is very advantageous because the process takes place even without a significant arc in the short-circuiter. There is therefore no additional impedance and no pressure wave, which may lent in the first embodiment of the invention, the contact closure counteracts.

At higher currents, the hollow cylinder also does not melt or evaporate uniformly, as a result of which individual metallic bridges remain, and thus the arc-free behavior of the short-circuiter is maintained far into the kA range.

An arc arises quasi only when the hollow cylinder is completely evaporated and the main contacts may not have been completely closed.

In the case of an arc ignition at high currents, a larger cavity or in addition a vent may be provided which limits the pressure build-up and thus the resulting counter forces.

The arrangement of the sacrificial element, the main contacts and the gas flow is chosen or designed so that in an arc ignition of the arc commutes immediately from the auxiliary path with the switching element 9 on the two contact electrodes 2 and 6. As a result, in this case the switching element 9 can already be relieved of the current flow before closing the contact electrodes.

In order to ensure the arcing freedom even at high currents, in addition, another stage of the current transfer can be realized before closing the main contacts. Here, the use of a sliding contact or a low-melting material is possible.

According to the illustrations according to FIGS. 1 and 2, there is accordingly an electrically conductive housing 1 with a movable contact electrode element 2, which is prestressed under the action of a spring 4. The movable contact electrode 2 is insulated from the electrically conductive housing 1 by means of an insulation 3. In the center of the fixed contact electrode 6 is an auxiliary contact 8 for the switching element 9 and a terminal for the switching element 9. Furthermore, here is an insulation 7, to the electrically conductive housing 1 and the contact electrode 6 is present. Reference numeral 10 symbolizes a conductive substance that can be used as a complete or partial filling of the hollow cylinder sacrificial element 5.

In this embodiment of Fig. 2, the conductive substance 10 may be e.g. be designed as a low-melting metal or conductive liquid.

As can be seen in FIGS. 3 to 6, the basic construction of the short-circuiter, as shown in FIGS. 1 and 2, can be inverted by the operating principle.

According to Fig. 3, the sacrificial element 5 is not loaded on compressive strength by the spring preload, but there is a stress on train instead.

This embodiment makes it possible to use inexpensive wires or rods as the sacrificial element 5. The sacrificial element of the second embodiment, in addition to the high tensile strength necessary for this design on a low melting integral. On a guide 11, which also forms a transition region to the sacrificial element 5, an auxiliary electrode 8 for the switching element 9 and a corresponding terminal is provided. The spring 4 has, according to FIG. 3, a guide 12, which is used with an element 13 for transmitting power to the movable contact electrode 14.

The elements 12 and 13 form a labyrinth seal, with the result that with a pressure increase in the seal interior, a movement support of the piston-like movable contact electrode 14 is ensured.

By using tensile wires, e.g. made of steel, very low melting integral of the sacrificial element 5 can be achieved at very high spring forces. This allows the use of inexpensive switching elements 9 and it can be achieved very low switching times of the contact electrodes.

In contrast to the embodiment variants according to FIGS. 1 and 2, the pressure wave generated by the arc in the variants according to FIGS. 3 to 6 does not counteract the closing movement of the contact electrodes, but can be used to accelerate the movement, as described above with reference to FIGS piston-shaped design one of the contact electrodes set forth has been. However, there is also the alternative, by the design of the parts 12 and 13 with a suitable choice of material to achieve a sliding contact-like arrangement, which leads the current to close the main contacts. For this purpose, in the case of a permanently conductive contact, a matching of the current distribution between the sacrificial element and the parts 12 and 13 is required. However, it is also conceivable that the parts 12 and 13 are electrically contacted only after a minimal movement or that the contact takes place by a voltage flashover in the form of breakdown or slip over a small distance due to the ignition of the arc at the sacrificial element 5.

In the embodiments according to illustration of FIGS. 1 to 3 and the necessary high current carrying capacity of the contact electrodes, it may be problematic that in each case a contact electrode including the contact point is movable. In addition to the high demands on the contact point, this also leads to large moving masses and thus to high contact forces. However, the mass and the necessary contact forces can be reduced by the choice of suitable materials and constructive variants.

In addition, constructions can be used in which the current forces support the movement of the moving element.

FIG. 4 shows a variant embodiment with a wire-shaped sacrificial element 5, specifically with the aim of reducing the moving mass, which is also conceivable in principle with the tubular sacrificial elements which are under spring pressure according to FIG. 1.

The contact electrodes 6 and 14 shown in FIG. 4 are fixed and only a movable contact plate 15 is used, which forms a bridge with respect to the contact electrodes 6 and 14.

The arrangement shown in principle in FIG. 4 can also be realized in a coaxial-symmetrical manner analogous to the representation according to FIG. 5. The advantage of this embodiment is the small moving mass of the contact plate 15 and the low requirements in terms of current carrying capacity and the dynamic load of the connection between the contact plate 15 and one of the fixed main electrodes 6 and 14, which in the case of the embodiment of FIG. 5 was realized centrally.

In principle, the power supply to the contact plate or to the sacrificial element can also be effected via a sliding contact of one of the fixed electrodes.

For this purpose, it is possible to electrically connect the part 15 via a sliding contact with the first fixed main electrode 6. As shown in FIGS. 5 and 6 showing exemplary coaxial structures, the second fixed contact electrode 14 is isolated from the case 1 by a part 7.

In the arrangement according to FIG. 6, a low-melting solder 10 or similar material may still be located in the bottom of the second fixed main electrode 14. This solder substance 10 can be forced between the fixed contacts 6 and 14 when heated, which increases the size of the conductive contact surface significantly.

In the case of the illustration of FIG. 6, the fixed main electrode 14 is formed as a pot electrode, wherein the movable contact plate 15 when immersed in the melting solder 10 displaces this as mentioned above.

The described short-circuiting allow the use of a self-extinguishing switching element such as spark gaps or thyristors, the application of a useful especially in the low voltage operating method for initiating a metallic short circuit.

In the high and medium voltage range, short circuits often occur in systems due to aging or contamination of the insulation sections as a rollover or breakdown. These insulation stretches are permanently damaged and would lead to a repeated fault in a renewed connection of the mains voltage. In the case of low voltage, however, short circuits often occur only as a result of so-called wipers, ie in the low-voltage range, short-circuits result from short-term conductive connections of different potentials or due to connections with only a very low current-carrying capacity. These connections may arise from falling parts, animals or split veins and the like. In some cases, sparks or arcs that arise spontaneously go out.

Permanent damage to the insulation due to aging or contamination as the cause of short circuits in the plant area is rather low. The maintenance effort within the plants often arises only as a result of the effect of a long-lasting arc fault. On the other hand, if the influence of the arc can be severely limited, it is possible to often forego immediate maintenance. Due to the peculiarities of fault generation and the duration of the fault in low-voltage systems, a special situation arises for the use of a short-circuiting device to reduce the effect of arcing faults.

In the case of fast-acting short-circuiters, the short circuit is initiated within the first residual current half-wave, permanently until it is disconnected by the upstream protective devices. The entire system is thus disconnected from the grid. As a result, even with possibly self-extinguishing wipers as a result of the shutdown is a high loss of use. On the other hand, if the duration of the response of the short-circuiter is delayed, the damage to the equipment in the case of a real damage event, on the other hand, increases considerably. In addition, a drastically higher maintenance costs. A delay of the short-circuiter also makes any desired personal protection unthinkable.

By using the short-circuiting device according to the invention with series connection of sacrificial and switching element, the apparently contradictory demands for high system availability on the one hand and a strong damage limitation on the other hand can be met. The inventive principle of the method for initiating a short circuit is based on a staggered connection of the short-circuiter with the following timing.

After the detection of a fault, z. B. a fault arc in the system, the switching element of the short-circuiter is briefly actuated. The possible short-circuit current through the switching element is limited by the sacrificial element and the impedance of the terminal and of the switching element. The current commutes from the fault location to the short circuiter. After an adjustable time, the switching element interrupts the short-circuit current and the system and the fault location are again loaded with mains voltage. In the case of a wiper and a sufficient reconsolidation of the fault remains the supply of the system. The short-circuiter reports the error that has occurred and thus indicates a necessary system check.

If the error persists, the switching element of the short-circuiter is controlled again and permanently. The sacrificial element of the short-circuiter is overloaded in this case and generates a permanent metallic short circuit, which forces a shutdown of the system.

In the proposed solution, the sacrificial element is designed so that a metallic short circuit can already be achieved after the lowest current loads (low I ² t values). The switching elements used in this case must thus have only a very low current carrying capacity or a low switching capacity.

For an application of the described method, while maintaining the construction, a differentiated design of the sacrificial element and the switching element is recommended. As an alternative to an almost opposite optimization of the presented short-circuiting device, however, this can be improved by a parallel path for the described method. Thus, an inexpensive and needs-based extension of the simple Kurzschiießers at any time for the use of the method explained possible. Fig. 7 shows a schematic representation with respect to the parallel connection of another path. The additional parallel path consists essentially of a controllable switching element 17 with medium to high current carrying capacity and breaking capacity. In addition, an impedance 16 may be provided. With the help of the impedance, it is possible to influence the magnitude of the short-circuit current or the value of the square-wave current pulse, for example with non-linear impedances. On the one hand, this can be useful in order to avoid a response of possible overcurrent or undervoltage protection devices of the network during the first time-limited switching of the switching element and, on the other hand, not to exceed the maximum load with regard to current carrying capacity and extinguishing capability for less powerful switching elements.

However, the height of the impedance 16 should not exceed a few 100 mΩ, since otherwise a commutation of the fault current to the overall device (short circuit path 1 and 2) is severely hindered. Preferably, the impedance should be less than a few mΩ.

As the switching element 17, semiconductor switches, e.g. Thyristors or IGBTs, but also triggerable vacuum switch and spark gaps suitable.

Claims

claims

1. short-circuiting device for use in low and medium voltage equipment for property and personal protection, comprising a switching element which is actuated by the trigger signal of a fault detection device, two opposing contact electrodes with means for power supply, which can be contacted to a circuit with terminals of different potential , Furthermore, the contact electrodes, under mechanical bias standing, in the case of short circuit spring assisted perform a relative movement to each other, a sacrificial element as a spacer between the contact electrodes and an electrical connection between the sacrificial element and the switching element on the one hand and one of the contact electrodes on the other hand, a current flow induced thermal destruction of the sacrificial element purposefully bring about, characterized in that the sacrificial element is a thin-walled hollow cylinder with a ratio between diameter and wall thickness of the hollow cylinder is greater than 10: 1 made of a refractory metallic material.

2. Short-circuiting device according to claim 1, characterized in that an electrically conductive substance is received in the hollow cylinder.

3. short-circuiting device according to claim 2, characterized in that between the conductive substance and the hollow cylinder, an insulating layer of lesser mechanical strength and temperature resistance is provided as the material of the hollow cylinder.

4. Short-circuiting device according to one of the preceding claims, characterized in that the hollow cylinder is inserted and guided in recesses of the contact electrodes.

5. Short-circuiting device according to one of the preceding claims, characterized in that in the fixed contact electrode, an insulating body and a Hilfselek- electrode are located, wherein the auxiliary electrode is in communication with the sacrificial element.

6. short-circuiting device according to one of the preceding claims, characterized in that the opposing sides of the contact electrodes have a complementary conical shape,

7. Short-circuiting device according to one of the preceding claims, characterized in that the hollow cylinder distributed over the wall thickness structures for the formation of current paths with the result of uneven heating at current load and a deformation with concomitant loss of mechanical strength.

8. Short-circuiting device according to one of the preceding claims, characterized in that between the contact electrodes, a cavity is formed to receive parts of the destroyed sacrificial element.

9. short-circuiting device according to one of the preceding claims, characterized in that between the contact electrodes in the closed state, a venting channel or a vent hole is effective.

10. Short-circuiting device according to one of the preceding claims, characterized in that the means for generating the biasing force is a compression spring.

11. Short-circuiting device for use in low-voltage and medium-voltage systems for property and personal protection, comprising a switching element which can be actuated by the triggering signal of an error detection device, two opposing contact electrodes with means for power supply, which are contactable to a circuit with terminals of different potential, continue the contact electrodes, under mechanical bias standing, in the case of short circuit spring assisted perform a relative movement to each other or the contact electrodes are bridged by a biased contact element then when the contact element performs a relative movement to the contact electrodes, a sacrificial element as a spacer between the contact electrodes and with an electrical connection between the sacrificial element and the switching element on the one hand and one of the contact electrodes on the other hand to cause a current flow induced thermal destruction of the sacrificial element, characterized in that the sacrificial element is a wire or rod of a low melting integral conductive material, the sacrificial element being under tension is provided with mechanical bias and between the contact electrodes labyrinth-like, interlocking sealing elements are provided to effect a movement support of the piston-like movable contact electrode or the bridge-like contact element in an arcing and pressure development.

12. Short-circuiting device according to claim 11, characterized in that the movable contact electrode forms a contact bridge between two electrical connections.

13. Short-circuiting device according to claim 11, characterized in that the switching element is connected to the movable contact electrode.

14. Short-circuiting device according to claim 11, characterized in that the switching element is connected to the fixed contact electrode.

15. Short-circuiting device according to claim 11, characterized in that the movable contact electrode is designed as a displacement punch, which cooperates with a solid pot contact electrode, wherein in the pot contact electrode, a conductive, low-melting substance is located, which forms a complementary electrical bridge between the opposite contact portions when immersing the punch.

16. A method for initiating a short circuit in low-voltage systems using a short-circuiting device according to one of the preceding claims, characterized by a staggered connection of the short-circuiting device with the following steps:

- Short-term driving of the switching element after detection of a fault case;

Limiting the short-circuit current through the switching element by means of the sacrificial element and by the impedance of the terminal and the impedance of the switching element itself and commutation of the current from the fault location to the short-circuiter;

- interrupting the short-circuit current after a predetermined time by the switching element and re-loading the system with mains voltage;

if necessary, if the fault continues, renewed, now permanent activation of the switching element;

- Destruction of the sacrificial element and generating a permanent short circuit with shutdown of the system.