DE19851047C2 - Current limiting arrangement with damping element - Google Patents

Description

The invention relates to a current limiting arrangement for limiting a current in an electrical circuit according to the preamble of Claim 1.

A device with the Merk mentioned in the preamble of claim 1, which, however, does not serve to limit the current in electrical circuits, but serves to reduce iron losses in alternating current electrical devices, is known from DE-PS 406 372. The embodiment shown in Fig. 1 of DE-PS 406 372 shows a transformer with a core with three parallel legs, which are connected to each other at their ends by a common yoke. The primary and secondary windings are guided around the two outer legs, an auxiliary coil is penetrated by the middle leg. In contrast to the primary coil, this auxiliary coil is supplied with a high-frequency alternating voltage, which serves to magnetically fluidize the transformer core in order to reduce the amount of energy to be applied by the primary coil for magnetizing the core. A disadvantage of this arrangement is that this "magnetization aid" accelerates saturation of the core through the auxiliary coil on the central leg.

DE-PS 830 979 discloses a transformer with a useful core and litter core. This is also not a current limiter. Out this document is known the magnetic resistance of the way of a magnetic flux in a transformer core by providing one Increase air gap. The problem of core saturation is in this pressure font not addressed.  

The area of application and the functional principle of Current limiting arrangements outlined:

In general, most electrical circuits have protection measures taken against excessive currents caused by a temporary load impedance or a fault current can be caused. The commonly used fuses or circuit sub breakers that switch the circuit at a predetermined current level or a open predetermined current-time product, but act slowly and cannot respond to fast events. They are also circuit breakers only available for relatively low currents.

In order to overcome the above drawbacks, various currents were used delimiter suggested that together with fuses or circuit interrupters are to be used. One of them is a superconducting one Current limiting arrangement, which has the magnetic flux cancellation effect of a superconductor.

Referring to FIG. 1, the magnetic flux cancellation effect of a superconductor 100 is illustrated. When the superconductor 100 a magnetic field H is exposed, that induced in the superconductor 100 includes a current I is below a critical value, there is the superconductor 100 in a superconducting state. A reversed magnetic field -H is then generated on the basis of the current I, namely in a direction for extinguishing the magnetic field H acting on the superconductor 100. As a result, the magnetic field H flowing through the superconductor 100 is extinguished by the reversed magnetic field -H.

If, on the other hand, there is a magnetic field H which induces a current exceeding the critical value in the superconductor 100 , the superconductor 100 goes into a resistive state, the transition from the superconducting state to the resistive state extremely weakening the reverse magnetic field -H, which leads to a loss of the magnetic flux extinction property of the superconductor 100 . As a result, the magnetic field H flowing through the superconductor 100 is not extinguished by an inverted magnetic field -H.

Referring now to FIG. 2, there is shown an exemplary electrical device 5 with a conventional superconducting current limiting arrangement 10 , which uses the magnetic flux cancellation effect of a superconductor. The superconducting current limiting arrangement 10 comprises a primary winding 110 , a superconducting element 120 and a saturable magnetic core 130 , the primary winding 110 electrically coupling the superconducting current limiting arrangement 10 via connections A and B to an external circuit 20 which, for example, has a voltage source Vs and a load resistor R _L includes. In the figure, the primary winding 110 is shown in the form of a conductive coil and the superconducting element 120 in the form of a superconducting ring.

In the electrical device 5 and the primary winding 110 flows through the load resistor R _L a by the voltage source Vs and the total impedance of the electrical device 5 certain circuit current. The total impedance is mainly determined by the load resistance R _L and an additional impedance which is caused by the superconducting current limiting arrangement 10 .

The mode of operation of the electrical device 5 shown in FIG. 2 will now be explained with reference to FIG. 3.

Under normal conditions, when a current flows in the primary winding 110 below a transition point P in FIG. 3, the superconducting element 120 remains in the superconducting state. As previously explained with reference to FIG. 1, therefore, the reversed or opposite magnetic flux generated by the superconducting element 120 extinguishes the magnetic flux caused by the primary winding 120 , which makes the inductance of the primary winding 110 almost zero. Since the impedance of the superconducting current limiting arrangement 10 is only determined by its leakage inductance and the ohmic resistance of the primary winding 110 , the additional impedance caused by the superconducting current limiting arrangement 10 is consequently very low, which is why the normal current can flow through the electrical device 5 without that a significant change in resistance occurs due to the superconducting current limiting arrangement 10 .

Under fault conditions, however, so if an error caused, for example, by a transient load impedance change or a fault current fault current above the transition point P in Fig flowing in the primary winding 110. 3,, the superconducting element 120 is in the resistive state, as the fault current in the primary winding 110 a magnetic Generates flux that induces a current in the superconducting element 120 above the critical value. Therefore, the magnetic flux generated by the primary winding 110 cannot be extinguished by the reverse magnetic flux generated by the superconducting element 120 , as explained above in connection with FIG. 1. Accordingly, as soon as a transition from the superconducting state to the resistive state occurs in the superconducting element 120 , the resulting net magnetic flux suddenly increases the inductance seen at the terminals A and B; the same applies to the impedance of the superconducting current limiting arrangement 10 . As a result, the total impedance of the electrical device 5 increases abruptly, so that the level of the leakage current flowing through the electrical device 5 can be limited.

Such superconducting current limiting arrangements are for example from Gerlach, H .; Müller K .: "Superconducting short-circuiters and current limiting devices", in: Elektrie 31 ( 1977 ) H. 11, and from the documents DE 195 24 579 C2, DE 44 18 050 A1, DE-OS 23 00 022 and DD 94 221 known.

However, as shown in FIG. 3, if the leakage current is not limited by an impedance change caused by the superconducting current limiting arrangement 10 and approaches a saturation point Q where the magnetic core 130 saturates, the inductance of the primary winding 110 falls on one significantly smaller value, which also applies to the additional impedance of the superconducting current limiting arrangement 10 . As a result, when the magnetic core 130 is finally saturated, an extremely large leakage current can flow through the external circuit and destroy it.

DE 196 28 358 C1 relates to the problem of core saturation to mention the a superconducting short-circuit current limiter shows that in the event of a fault current of the inductively coupled Load switching in sections goes into saturation. This serves magnetically decouple the superconductor from the primary coil of the load circuit peln, so as the required cooling capacity of the cryostat of the superconductor to be able to reduce. In contrast to the unwanted saturation of the The core of the previously described prior art is the current limitation zer of DE 196 28 358 C1 initially targeted a saturation in sections brought about.  

The above-mentioned saturation problems can be caused by this, for example be overcome that the superconducting current limiting arrangement is designed to tolerate a high saturation current. This however, it can cause a significant increase in size, weight and the cost of all elements of the superconducting current limiting arrangement, especially the magnetic core.

The object of the invention is therefore the saturation problems of the magneti core without loosening its cross-sectional area.

According to the invention, this object is achieved by a current limitation arrangement with the features of claim 1.  

Advantageous further developments are given in the dependent claims en.

The invention will now be described with reference to the accompanying drawings explained in more detail. They represent:

Fig. 1 shows the Magnetflußauslöschungseffekt a superconductor,

Fig. 2 is an electric device having a conventional supralei Tenden current limiting arrangement,

Fig. 3 shows the magnetization curve of a magnetic core in a superconducting current limiting device,

Fig. 4 is a superconducting current limiting device according to a first embodiment of the invention,

Fig. 5 is a superconducting current limiting device according to a second embodiment of the invention,

Fig. 6 is a superconducting current limiting device according to a third embodiment of the invention,

Fig. 7 an inductor according to the invention and

Fig. 8 shows a transformer according to the invention.

In Figs. 4 to 6 superconducting current limiting arrangements are shown by preferred embodiments of the invention. In FIG. 4 one recognizes a superconducting current limiting device 10A according to a first embodiment of the invention. The superconducting current limiting arrangement 10 A comprises a magnetic core 50 with a plurality of, for example, three magnetic branch sections (or legs), for example first to third magnetic legs 58 A to 58 C, which are located between two elongate sections (or yokes), for example an upper yoke 58 D and a lower yoke 58 E, extend. The magnetic core 50 can be made of any magnetically saturable material that has a saturated and an unsaturated state. The second magnetic leg 58 B has a gap 55 , for example an air gap, which is occupied by a material whose permeance (magnetic conductivity) is smaller than that of the magnetic core 50 . In other words, the gap is filled with a material whose reluctance is greater than that of the magnetic core 50 . The superconducting current limiting arrangement 10 A is also coupled to an external circuit (not shown), with the aid of an input coil 52 , i.e. a primary winding, which is connected to the external circuit via two connections A and B, as is the case in FIG Fig. 2 electrical device shown is the case. The superconducting current limiting arrangement 10 A also comprises, as in FIG. 2, a superconducting element 54 and also a damping element 56 enclosing the second magnetic leg 58 B with the gap 55 . The primary winding 52 is in the form of a coil with a predetermined number of turns, which is wound around a preferably gapless magnetic leg, such as the first magnetic leg 58 A, or the superconducting element 54 ; it is made of a conductive material, which can either be a superconducting material or a non-superconducting, that is to say normal conducting, material. The superconducting element 54 is formed by a super conductor in the form of, for example, one or more rings, cylinders, short-circuited coils or the like, wherein it is penetrated by a yoke or a gapless magnetic leg.

The primary winding 52 and the superconducting element 54 can also be located in another part or in other parts of the magnetic circuit 50 , apart from a magnetic leg with a gap. To be more specific, the primary winding 52 and superconducting element 54 can be side by side, i.e. side by side, as in Fig. 2, or they can, as shown in Figs. 4 and 5, either on a certain gapless magnetic Legs or on a yoke of the magnetic core 50 may be arranged one inside the other. Alternatively, the primary winding 52 or the surpal-conducting element 54 can be arranged on a yoke or a magnetic leg without a gap, while the respective other element rests on another yoke or another magnetic leg without a gap. However, it is preferred that the primary winding 52 and the superconducting element 54 are arranged together, that is, one inside the other, as shown in FIGS. 4 and 5. When the primary coil 52 and the superconducting element 54 are arranged separately to the magnetic core 50, leakage fluxes can occur, which can not be extinguished by the superconducting element 54, the magnetic flux thereby canceling effect of the superconducting element may deteriorate 54th

In the preferred embodiment of the invention, the damping element 56 is formed from a superconducting material and is in the form of one or more rings, cylinders, short-circuited coils or the like; it is penetrated by a magnetic leg with a gap, for example the second magnetic leg 58 B. In the example shown in Fig. 4 embodiment, the damping member 56 comprises three superconducting rings, which are stacked axially one above the other and the second magnetic leg enclose 58 B.

The operation of the superconducting current limiting arrangement 10 A is explained with reference to FIGS. 3 and 4.

Under normal conditions, that is, when a normal current flows into the primary winding 52 within a certain predetermined range, for example below the point P shown in FIG. 3, the superconducting element 54 remains in the superconducting state, since in the superconducting element 54 due to the normal current a current is induced in the primary winding 52 which is below a critical value. Therefore, the magnetic flux generated by the primary winding 52 is extinguished by the corresponding reverse magnetic flux generated by the superconducting element 54 , so that no magnetic flux passes through the magnetic core 50 . As a result, the inductance seen at terminals A and B is very small, which makes the impedance of the superconducting current limiting arrangement 10 A low. The superconducting current limiting arrangement 10 A thus has a negligible influence on the function of the external circuit.

On the other hand, when a fault current flows into the primary winding 52 under the fault condition, which exceeds the predetermined range and generates a magnetic flux which induces a current exceeding the critical value in the superconducting element 54 , the superconducting element 54 goes into the resistive state and loses hereby its magnetic flux extinction property. The impedance of the superconducting current limiting arrangement 10 A then increases, whereby the level of the fault current flowing through the external circuit can be limited.

In the conventional superconducting current limiting arrangement 10 shown in FIG. 2, if the leakage current is not suppressed and instead increases continuously until it reaches a saturation point, such as the point Q shown in FIG. 3, where the magnetic core 130 is saturated, it decreases the impedance of the superconducting current limiting arrangement 10 again rapidly, so that an extremely large fault current can flow through the external circuit and damage it.

According to the invention, however, this saturation problem is solved in that the saturation of the magnetic core 50 is delayed or prevented, by utilizing the combined effect of the gap 55 and the damping element 56 of the second magnetic leg 58 B.

Under fault conditions, two parallel magnetic paths, namely a first closed path 59 via the first and third magnetic legs 58 A, 58 C, and a second closed path 57 via the first and second magnetic legs 58 A, 58 B, in the magnetic core 50 is formed in accordance with the magnetic flux density in the magnetic core. In other words, there are three magnetic paths in the magnetic core 50 , namely a main magnetic path via the first magnetic leg 58 A for the total magnetic flux generated in the magnetic core 50 , a primary magnetic path via the third magnetic leg 58 C for a predominant part of the total magnetic flux and a secondary magnetic path via the second magnetic leg 58 B for the rest of the total magnetic flux.

Specifically, the following applies: until the third magnetic leg 58 C is saturated, the permeance of the third magnetic leg 58 C of the magnetic core 50 is greater than that of the second magnetic leg 58 B with the gap 55 and the damping element 56 , since the permeance of the second magnetic leg 58 B is very small and approximately constant due to the gap 55 . Therefore, the magnetic flux generated by the primary winding 52 primarily runs along the first closed path 59 . When the magnetic flux becomes strong and thus the magnetic flux through the magnetic legs 58 A and 58 C comes close to the saturation point, the permeance of the third magnetic leg 58 C decreases, while the second magnetic leg 58 B has its approximately constant permeance maintains. Therefore, the magnetic flux begins to run along the second closed path 57 . The conditions for the magnetic flux distribution under the magnetic legs can be controlled by the properties of the magnetic core 50 , for example the gap width of the gap 55 .

In particular, when a relatively low leakage current flows into the primary winding 52 and the permeance of the third magnetic leg 58 C is still greater than that of the second magnetic leg 58 B with the gap 55 , the magnetic flux generated by the primary winding 52 primarily passes through the third magnetic leg 58 C, that is along the first closed path 59 , whereas the proportion of the magnetic flux running through the second magnetic leg 58 B, that is to say the second closed path 57 , is negligible.

However, when the fault current increases and the 58 C passing through the third magneti's leg magnetic flux approaches the saturation point, the permeance takes the third magnetic leg 58 C., the proportion of the 58 C flowing through the third magnetic leg magnetic flux gradually smaller becomes. On the other hand, the permeance of the second magnetic leg 58 B remains constant, as previously explained; consequently, the proportion of the magnetic flux flowing through the second magnetic leg 58 B gradually increases. However, since the proportion of the magnetic flux flowing through the second magnetic leg 58 B is still small in comparison with that of the third magnetic leg 58 C, the damping element 56 continues to retain its magnetic flux cancellation property. Therefore, the magnetic flux passing through the second magnetic leg 58 B is extinguished by a reverse magnetic flux generated by the damping element 56 . Accordingly, there is no magnetic flux that passes through the second magnetic leg 58 B; the magnetic flux passing through the magnetic core 50 does not easily reach its saturation point due to the extinction of the magnetic flux running along the second magnetic leg 58 B. As a result, the saturation problems of the magnetic core 50 do not occur, so that an abrupt increase in the leakage current can be avoided.

In this embodiment, the amount of magnetic flux passing through the second magnetic leg 58 B is proportional to the ratio of the reluctance of the third magnetic leg to the reluctance of the second magnetic leg. This means that as the permeability of the third magnetic leg 58 C decreases, the magnetic flux passing through the second magnetic leg 58 B becomes stronger, but this is reversed by the damping element 56 , since the damping element 56 has the magnetic flux explained in connection with FIG. 1 has extinction property.

As described above, according to the invention, the superconducting current limiting arrangement 10 A can detect and limit fault currents without an external control unit, since part of the magnetic flux generated by the fault current is extinguished by the damping element 56 and thereby prevents the magnetic core 50 from becoming saturated .

In Fig. 5, a superconducting current limiting device is shown 10 B according to a second embodiment of the invention, said superconducting current limiting arrangement 10 B comprises a magnetic core 60 with a gap 65 and a damping 66th The second and third magnetic legs of the magnetic core 60 are interchanged in this exemplary embodiment; the damping element 66 is in the form of a superconducting cylinder instead of the superconducting rings as shown in FIG. 4.

With the exception of the position of the second and third magnetic legs and the shape of the damping element, the superconducting current limiting arrangement 10 B according to this exemplary embodiment is functionally identical to the arrangement 10 A shown in FIG. 4, which is why the structure and its mode of operation are not explained becomes.

In FIG. 6, a superconducting current limiting device is shown 10 C according to a third embodiment of the invention, this superconducting current limiting device 10 includes C a magnetic core 61 having first to third magnetic legs 62 A to 62 C and a damping 63rd In this exemplary embodiment, the entire second magnetic leg 62 B of the magnetic core 61 is made of a material whose permeance is smaller than that of the third magnetic leg 62 C, in contrast to the second magnetic leg 58 B in FIG. 4, of which one Is part of a gap filled with a low permeance material.

Since the superconducting current limiting arrangement 10 C according to this exemplary embodiment is functionally identical to the arrangement 10 A shown in FIG. 4, the explanation of its construction and its mode of operation is dispensed with.

Although preferred embodiments with regard to magnetic cores three magnetic legs have been described, the number of magnetic leg can of course be changed. For example the magnetic core can have one or more magnetic legs comprise, each having a gap and a damping element, so the behavior related to the distribution of the magnetic flux too improve and thereby effectively prevent the magnetic core in Saturation goes. Similarly, the number of magnetic legs larger than two can be selected without a gap and without a damping element.  

As described above, according to the invention, the superconducting Current limiting arrangement an abrupt decrease in the inductance of the Prevent primary winding under fault conditions because the saturation of the magnetic core is effectively prevented. As a result, a verbes achieved current limiting behavior.

In addition, since the superconducting current limiting arrangement the Sätti problem without increasing the cross-sectional area of the magnetic core can avoid the manufacturing costs of the superconductors the current limiting arrangement can be greatly reduced.

The means of a gap and a damping element in the invention current limiting property achieved in a conventional Inductor (or regulator) for regulating current fluctuations in one electrical circuit can be used.

In Fig. 7, an inductor 75 is shown which is connected to an external circuit 70. The inductor 75 comprises a magnetic core 76 with three magnetic legs 78 A, 78 B and 78 C, a primary winding 72 being arranged on the first magnetic leg 78 A and a damping element 74 in the form of, for example, a superconducting ring, the second magnetic leg 78 B, which has a gap, encloses. Magnetic core 76 may include more than three magnetic legs, but should include at least one magnetic leg with a gap and more than one magnetic leg without a gap.

With this structure of the inductor 75 , the primary winding 72 can be arranged in any part of the magnetic core 76 , with the exception of the magnetic leg with a gap.

When a fault current is coupled into the inductor 76, which causes the magnetic core 76 of its saturation state is approaching, begins a portion which is generated by the current flowing through the primary winding 72 Leakage of the magnetic flux to pass through the second magnetic leg 78 B, being extinguished by the magnetic flux generated by the damping element 74 . As a result, as already described in the previous exemplary embodiments, the saturation of the magnetic core 76 in the inductor 75 can be avoided and the fault current can be limited.

The current limiting property can also be obtained with a transformer that uses a magnetic leg with a gap and damping element. FIG. 8 shows a transformer 85 which is connected to a source circuit 80 and to a load circuit 81 . The transformer 85 comprises a magnetic core 88 with a plurality of, for example, three magnetic legs 83 A, 83 B and 83 C, these magnetic legs comprising at least one magnetic leg with a gap and two or more magnetic legs without a gap. A primary winding 82 is arranged on the gapless first magnetic leg 83 A and connected to the source circuit 80 . A secondary winding 86 is arranged for example on the gapless third magnetic leg 83 C and connected to the load circuit 81 . The primary and secondary windings 82 and 86 can be made of a superconducting or a non-superconducting material. The primary winding 82 serves to feed an input energy from the source circuit 80 into the transformer 85 ; the secondary winding 86 serves to supply the load circuit 81 with a by the magnetic flux generated by the primary winding 82 and through the third magnetic leg passes 83 C, induced electrical output energy. A damping element 84 is provided in the form of a superconducting ring and encloses the second magnetic leg 83 B with a gap.

With this structure of the transformer 85 , the primary winding 82 and the secondary winding 86 can be arranged on any part of the magnetic core 88 , except for the magnetic leg with a gap.

When a fault current is injected into the primary winding 82 or the secondary winding 86 and the magnetic core thereby comes close to its saturation state, part of the magnetic flux generated by the fault current and through the magnetic legs 83 A and 83 C begins to flow magnetically through which to go through the second magnetic leg 83 B, wherein it is extinguished by the damping element 84 . As a result, as described in the previous embodiments, the saturation of the magnetic core 88 can be avoided. In this way, an increase in the fault current can be suppressed. By using the magnetic core with gap and damping element, an abrupt increase in the fault current flowing into the transformer can thus be effectively prevented, so that the transformer remains free of damage that could be caused by abnormal fault currents.

In the embodiments of the invention described so far, the Damping elements preferably made of a superconducting material, to maximize the magnetic flux cancellation property. The steam However, elements can also be made from a normal, non-superconducting material be made, for example Cu or Al. In such a case, however the magnetic flux cancellation effect due to the relatively large electrical Intrinsic resistance can be comparatively greatly reduced. The damping elements can take any form, for example one or more Cylinders, rings, short-circuited coils or the like, as long as they one or more closed paths for the one through the outer magne table flow can provide induced current. The gap width can be one decisive design parameter for the control of the magnetic flux ver sharing behavior between the magnetic legs, the is in turn decisive for the current limiting behavior.  

The magnetic legs 78 B and 83 B of the inductor 75 and the transformer 85 (which are shown in FIGS . 7 and 8) can also be made of a material of low permeability, as shown in FIG. 6.

In addition, the components formed from superconducting material should kept below the critical temperature of the superconducting material from which they are composed to their superconducting Maintain condition, for example with the help of one with one Coolant charged cryostat.

In the context of the invention, all known high-temperature or Low temperature superconducting materials are used. Prefers However, as a superconducting material, high-temperature superconducting material used with a critical temperature, the use a coolant such as liquid nitrogen.

In summary, a superconducting current limiting arrangement protects an electrical circuit against fault currents. The arrangement includes one magnetically saturable core with a saturated and an unsaturated Condition as well as an input coil to electrically connect the core with the to couple electrical circuit, the input coil carrying a current pulls, so that due to this current, a magnetic flux in the core is produced. The core includes a main path that leads to the one created total magnetic flux leads, as well as at least two magnetic Paths, a first a first part of the magnetic flux leads and a second leads a second part of the magnetic flux and has a damping element to the second part of the magnetic flux at least partially wiped out.

Claims (12)

1. current limiting arrangement for limiting a current in an electrical circuit,
the current limiting arrangement comprising:

• - A magnetically saturable core ( 50 ; 60 ; 61 ; 76 ; 88 ) with a primary magnetic flux circuit ( 59 ) and with at least one, arranged with respect to the primary magnetic flux circuit in magnetic parallel circuit, secondary magnetic flux circuit ( 57 ),
  wherein the core has the magnetic fluxes of both the primary magnetic flux circuit ( 59 ) and the at least one secondary magnetic flux circuit ( 57 ) leading first section ( 58 A; 62 A; 78 A; 83 A), further one exclusively the magnetic flux of the primary magnetic flux circuit ( 59 ) leading second section ( 58 C; 62 C; 78 C; 83 C), and finally an exclusively the magnetic flow of the at least one secondary magnetic flux circuit ( 57 ) leading third section ( 58 B; 62 B ; 78 B; 83 B), and
• - A on the first core section ( 58 A; 62 A; 78 A; 83 A) arranged coil ( 52 ; 72 ; 82 ) for inductive coupling of the electrical circuit to the core,

characterized by
that the third core section ( 58 B; 62 B; 78 B; 83 B) has, at least in sections, a higher magnetic resistance than the first core section ( 58 A; 62 A; 78 A; 83 A) at least in a magnetically unloaded state of the core and the second core section ( 58 C; 62 C; 78 C; 83 C), and
that the current limiting assembly further comprising at least one of the third core portion (58 B; 62 B; 78 B; 83 B) arranged Dämpfele ment (56; 63; 66; 74; 84), wherein, in the at least one damping member (56; 63 ; 66 ; 74 ; 84 ) flowing current is finally magnetically induced and wherein the at least one damping element ( 56 ; 63 ; 66 ; 74 ; 84 ) extinguishes at least part of the magnetic flux of the at least one secondary magnetic flux circuit ( 57 ). 2. Arrangement according to claim 1, characterized in that the third core section ( 58 B; 62 B; 78 B; 83 B) contains flux influencing means ( 55 ; 65 ; 62 B) to cause the magnetic flux of the at least one secondary Magnetic flux circuit ( 57 ) compared to that of the primary magnetic flux circuit ( 59 ) is negligible when the second core section ( 58 C; 62 C; 78 C; 83 C) is in a magnetically unsaturated state, and the magnetic flux of the at least one secondary magnetic flux circuit ( 57 ) becomes large when the second core section ( 58 C; 62 C; 78 C; 83 C) approaches a saturated state. 3. Arrangement according to claim 2, characterized in that the flow influencing means ( 55 ; 65 ; 62 B) comprise a gap ( 55 ; 65 ) sen. 4. Arrangement according to claim 3, characterized in that the gap ( 55 ; 65 ) is an air gap ( 55 ; 65 ). 5. Arrangement according to one of claims 2 to 4, characterized in that the flow influencing means ( 55 ; 65 ; 62 B) comprise a material whose permeance is smaller than that of the second Kernab section ( 58 C; 62 C; 78 C; 83 C) is. 6. Arrangement according to one of claims 1 to 5, characterized in that the damping element ( 56 ; 63 ; 66 ; 74 ; 84 ) in the form of one or more rings ( 56 ; 63 ; 74 ; 84 ), cylinder ( 66 ) or Kurzge closed coils is formed. 7. Arrangement according to one of claims 1 to 6, characterized in that the damping element ( 56 ; 63 ; 66 ; 74 ; 84 ) is made of a superconducting material. 8. Arrangement according to one of claims 1 to 7, characterized in that it comprises superconducting means ( 54 ) to cause a major part of the magnetic flux generated to be extinguished when the current flowing through the coil ( 52 ) within a predetermined range, the superconducting means ( 54 ) going into a resistive state when the current exceeds the predetermined range, resulting in a subsequent increase in the device impedance. 9. Arrangement according to claim 8, characterized in that the superconducting means ( 54 ) on the first ( 58 A; 62 A; 78 A; 83 A) or the second core section ( 58 C; 62 C; 78 C; 83 C) are arranged. 10. The arrangement according to claim 8 or 9, characterized in that the superconducting means ( 54 ) are in the form of one or more rings, cylinders ( 54 ) or short-circuited coils. 11. Arrangement according to one of claims 8 to 10, characterized in that the superconducting means ( 54 ) inside or outside the coil ( 52 ) along the first ( 58 A; 62 A; 78 A; 83 A) or the second core section ( 58 C; 62 C; 78 C; 83 C) are arranged. 12. Arrangement according to one of claims 1 to 11, characterized in that it comprises an output coil ( 86 ) which is arranged along the first ( 83 A) or the second core section ( 83 C) and coupled to a load circuit ( 81 ) is to supply the load circuit ( 81 ) with electrical energy, which is induced by the magnetic flux, which passes through that core section ( 83 C) along which the output coil ( 86 ) is arranged.