EP1129459B1 - Use of a magnetic core for a current transformer, method for the production of a magnetic core and current transformer with a magnetic core - Google Patents

Description

The invention relates to the use of a magnetic core for a current transformer, a method for Production of such a magnetic core and a current transformer with such a magnetic core.

For recording the energy consumption of electrical appliances and Industrial and domestic plants become energy meters used. The oldest common principle is this the Ferrari counter. The Ferraris counter is based on the Energy counting over the rotation of a mechanical one Counter connected disc, by the current or voltage-proportional fields of corresponding field coils is driven. For the extension of Functionalities of energy meters such. For Multi-tariff operation or remote reading become electronic Energy meters are used in which the electricity and Voltage detection via inductive current and voltage transformers he follows.

A special application in which a particularly high Accuracy is required, is the detection of Energy flows in the area of Electricity utilities. Here, on the one hand generated by the respective power plants and in the High-voltage grids fed precise amounts of energy determined, on the other hand are for the account the changing proportions of consumption or delivery in traffic between the utilities of great Importance. The energy meters used for this purpose are Multifunction built-in appliances whose input signals for electricity and tension from the respective high and Medium voltage installations via cascades of electricity and electricity Voltage transformers are tapped and their Output signals for digital and graphical registration or display as well as for control purposes in the control room serve. Here are the network side first converter for potential-separated transformation of high current and Voltage values, e.g. 1 to 100 kA and 10 to 500 kV, in in Cabinets manageable values, the second transform this in the actual energy meter to that of the Measuring electronics require signal levels in the range of less than 10 up to 100 mV.

FIG. 1 shows an equivalent circuit diagram of such a current transformer and the areas of the technical data which can occur in different applications. Shown here is a current transformer 1. On a magnetic core 4, which is composed of an amorphous soft magnetic band, there is the primary winding 2, which leads the current I to be measured _prim and a secondary winding 3, which leads the measuring current I _sec . The secondary current I _sec is automatically adjusted so that the ampere-turns primary and secondary are ideally the same size and oppositely directed. The course of the magnetic fields in such a current transformer is shown in FIG. 2, whereby losses in the magnetic core are not taken into account. The current in the secondary winding 3 is then adjusted according to the law of induction so that it tries to prevent the cause of its formation, namely the temporal change of the magnetic flux in the magnetic core 4.

In the ideal current transformer, therefore, the secondary current multiplied by the ratio of the number of turns is negatively equal to the primary current, which is illustrated by equation (1): I ideal sec = -I prime * (N prime / N sec )

This ideal case is due to the losses in load resistance 5, in the copper resistor 6 of the secondary winding and in the Magnetic core 4 never reached.

In the real current transformer, therefore, the secondary current has an amplitude error and a phase error compared to the above idealization, which is described by Equation (2): Amplitude error: F (I) = I real sec - I ideal sec I ideal sec ; Phase error: φ =  (I real sec ) - (-I prime )

The output signals of such a current transformer are Digitized, multiplied, integrated and stored. The Result is an electrical quantity suitable for the mentioned Purposes is available.

Those used for energy counting in these applications electronic energy meters work "indirectly", so that only purely bipolar, zero-symmetrical alternating currents in the meter have to be measured themselves. Serve current transformers, the built with magnetic cores made of highly permeable materials are and to achieve low measurement error over a small Phase error φ with very many, i. typically 2500 and more, secondary windings must be equipped.

Current transformers are known for the imaging of purely bipolar currents whose magnetic cores consist of highly permeable crystalline alloys, in particular nickel-iron alloys, which contain about 80% by weight of nickel and are known under the name "permalloy". These have a basically very low phase error φ. But they have the disadvantage that this phase error φ varies greatly with the measured current I _prim , which is synonymous with the modulation of the converter core. For a precise current measurement with changing loads with these transducers therefore a complex linearization in the energy meter is required.

Furthermore, current transformers are known which are based on ironless air coils work. This principle is as so-called Rogowski principle known. This eliminates the Influence of the modulation on the phase error. Because the Requirements for the immunity to interference of such current transformers However, it must be very high to be a verifiable Enabling energy counting, these constructions are with equipped with elaborate shields against external fields, which means a high material and installation costs and therefore costly.

Furthermore, solutions are known in which one with a Air gap provided (sheared) ferrite pot core as Magnet core is used. These current transformers have a very good linearity, however, is due to the relative low permeability of ferrites a very high Number of turns in connection with a very large volume Magnetic core required to connect to the current transformer low phase angle to achieve. These on ferrite shell cores based current transformer also have also a high sensitivity to external Foreign fields on, so that also there shielding must be taken.

The invention is based on the object, a magnetic core specify that when used in a current transformer in comparison to the prior art, a higher accuracy of a zu allowed measuring current. Furthermore, a method for Production of such a magnetic core and a current transformer be specified with such a magnetic core.

The object is achieved by the use of a magnetic core for a current transformer, characterized in that the magnetic core consists of a wound band of an amorphous ferromagnetic alloy, has a saturation permeability greater than 20,000 and less than 300,000, has a saturation magnetostriction whose Amount is less than 0.5 ppm and is substantially free of mechanical stresses. The magnetic core has a magnetic anisotropy axis, along which the magnetization of the magnetic core is particularly easy to align and which is perpendicular to a plane in which a center line of the belt runs, that is, perpendicular to the direction of the wound belt. The alloy has a composition consisting essentially of the formula Co _a (Fe _1-x Mn _x ) _b Ni _c X _d Si _e B _f C _g wherein X is at least one of V, Nb, Ta, Cr, Mo, W, Ge, P, a to g in atomic% and where a, b, c, d, e, f, g and x meet the following conditions: 40 ≤ a ≤ 82; 3 ≤ b ≤ 10; 0≤c≤30; 0 ≤ d ≤ 5; 0 ≤ e ≤ 20; 7 ≤ f ≤ 26; 0 ≤ g ≤ 3; with 15≤d + e + f + g≤33 and 0 ≤ x ≤ 1.

The permeability refers to an applied field strength, which lies in the plane in which the center line of the band lies, and the induced thereby induction.

It has been found that in such a magnetic core the Dependence of permeability on the magnetization very is small. The hysteresis loop of the magnetic core is so very narrow and linear.

Since the permeability is over 20,000 very large and also is essentially independent of the bias, are the absolute phase error and the absolute Amplitude error of a current transformer with such Magnetic core very small. The absolute amplitude error can be less than 1 ‰. The absolute phase error can be less than 0.1 °.

The current transformer has at least one magnet next to the core Primary winding and a secondary winding, to which a Burden resistor is connected in parallel and the the Low-impedance secondary circuit terminates.

It has also been found that the hysteresis loop of the magnetic core has a high linearity. Thus, a permeability ratio μ ₁₅ / μ ₄ <1.1 and a permeability ratio μ ₁₀ / μ _0.5 <1.25, where μ _0.5 , μ ₄ , μ ₁₀ and μ _{15 are} the permeabilities at a field amplitude H of 0.5 , 4, 10 and 15 mA / cm.

The small saturation magnetostriction and the orientation of the Anisotropy axis have a particularly advantageous effect on the high linearity of the hysteresis loop.

Due to the good linearity of the phase and the Amplitude error essentially no dependence on measuring electricity.

Since the absolute phase error, the absolute amplitude error and the dependence of the errors on the current to be measured very much are small, can be very accurate due to the current transformer Current detection done.

The invention is based on the finding that with the Alloy of the described composition by a suitable heat treatment a magnetic core with the described properties can be generated. There are very many parameters matched, so that the Magnetic core having the properties described.

The following is a heat treatment, which is a method for Production of a magnetic core is and also the task solves, describes:

After making and winding the tape to the magnetic core, the magnetic core is heated to a target temperature (relaxation temperature) between 380 ° C and 500 ° C. The magnetic core is cooled from the target temperature to room temperature, at the latest from the Curie temperature of the alloy, a magnetic field H> 100 A / cm, better> 1000 A / cm is turned on, which is parallel to the anisotropy axis of the magnetic core to be generated. The Curie temperature T _c is the temperature at which a spontaneous magnetization of the alloy begins. Depending on the alloy composition, which determines the location of the Curie temperature and the permeability level to be achieved, the cooling takes place at rates between 0.1 and 10 K / min. The temperature-time profile can be stationary, non-linear, continuous or unsteady. The cooling time can be between 0.25 and 60 hours.

The target temperature is chosen to be below the Crystallization temperature of the alloy is. Preferably the target temperature is at least 100 ° C below the Crystallization temperature of the alloy.

Furthermore, the target temperature is chosen so that in the alloys described a very small Saturation magnetostriction is achieved. The purpose required target temperature depends on the ratio of Fe, Mn to Co. The larger this ratio, the smaller the Target temperature selected to the smallest possible To obtain saturation magnetostriction.

By heating at the same time a balance mechanical Voltages and a small saturation magnetostriction achieved.

A particularly high linearity of the hysteresis loop lets to achieve if the ratio of mechanical elastic tension tensor of the magnetic core multiplied with the saturation magnetostriction for uniaxial anisotropy is less than 0.5.

It has been shown that the described duration for cooling causes that at the same time high saturation permeability one for a good linearity of the hysteresis loop sufficiently high anisotropy is achieved. By the described elimination of magnetostriction and stress It becomes possible, despite very small values of the uniaxial Anisotropy highly linear hysteresis loops with very high To produce permeabilities. The longer the cooling in the The magnetic field lasts, the smaller the Saturation permeability and the higher the anisotropy. This is because atomic regions of the alloy, have the magnetic dipole moments, below the Curie temperature in the magnetic field gradually more and more spatially Align so that a preferred direction for the Magnetization is formed, that is the anisotropy axis is formed. The more pronounced this orientation in the Magnetic field, the greater the uniaxial anisotropy, but the lower the permeability.

The alignment processes occurring in the magnetic field depend on the temperature in two ways. The higher the Temperature is, the more mobile are the atomic areas and so on they are easier to align. The lower the temperature, the greater the driving force of the magnetic field is on the magnetic dipole moments of the atomic regions, that is, the stronger the aligning power that is on the atomic areas acts. Through the described duration of Cooling, these factors were optimally matched tuned, so that at the same time high permeability for good linearity sufficiently high anisotropy is achieved.

The magnetic field is chosen such that the Saturation magnetization of the magnetic core in its axial Direction is safely reached.

To achieve high permeabilities, the composition the alloy selected such that the Curie temperature taking into account other parameters to be optimized, e.g. a high saturation induction, is as small as possible Curie temperature is for example between 190 ° C and 270 ° C. This is for technical and economic reasons advantageous because of linearity reasons below the Curie temperature can not be cooled field-free. A Lowering of the Curie temperature is first thereby ensures that the metalloid content, i. the proportion of Si and B is raised, with the saturation induction simultaneously also decreases. If, however, Mn additives within the added areas discussed, so can a lowering of the Curie temperature while maintaining the saturation induction be achieved.

At the same time, an increase in the metalloid content taking into account other parameters to be optimized, such as. the saturation magnetostriction, an increase in the Crystallization temperature achieved. This is advantageous because a high crystallization temperature is a better one Aging behavior of the magnetic core and a high Target temperature and thus better compensation of allows mechanical tension.

Further, in the choice of the composition of the alloy takes into account that the saturation induction of the magnetic core as big as possible. This is advantageous because at large Saturation induction of the linearity range is extended and so that a higher current can be measured reliably, before reaching saturation and thereby the linearity of the Current image is destroyed. The saturation induction is around the larger, the larger the ratio of Co, Fe, Mn to the rest the alloy is. At the same time it takes the Crystallization temperature from.

Due to the high permeability of the current transformer can at the same time exact current detection a particularly small volume exhibit.

With regard to the required properties, particularly good current transformers can be realized by the use of amorphous, ferromagnetic alloys having a magnetostriction value | λ _s | <0.1 ppm, the alloy having a composition consisting essentially of the formula Co _a (Fe _1-x Mn _x ) _b Ni _c X _d Si _e B _f C _g where X is at least one of V, Nb, Ta, Cr, Mo, W, Ge and P, a to g are in atomic% and where a, b, c, d, e, f, g and x meet the following conditions: 63 ≤ a ≤ 73; 3 ≤ b ≤ 10; 0≤c≤5; 0 ≤ d ≤ 3; 12 ≤ e ≤ 19; 7 ≤ f ≤ 20; 0 ≦ g ≦ 3 with 20 ≦ d + e + f + g ≦ 30 and x ≤ 0.5.

A further improvement can be achieved with current transformers containing as transducer core material amorphous, ferromagnetic alloys of the above type, in which a, b, c satisfy the following condition: 68 ≤ a + b + c ≤ 75.

The abovementioned alloy systems are characterized by very linear, extremely narrow hysteresis loops, wherein a permeability μ ₄ > 120000 at a field amplitude H and of 4 mA / cm can be set well with the described method.

The alloy systems according to the invention are virtually magnetostriction-free. The magnetostriction is preferably set by a heat treatment, so that linear hysteresis loops can be produced with an induction range which can be used over a wide area due to the high saturation induction of B _s = 0.5 to 0.7 T and a very good frequency response with respect to permeability and comparatively low remagnetization losses.

Such highly linear current transformers are the most achieved highlighted alloy compositions, as with a matched heat treatment, a zero crossing of the Saturation magnetostriction can be adjusted. In addition, can be exploited that in the usual Heat treatment for property setting the Temperature dependence of permeability in or very close to Zero crossing lies.

Due to the high saturation induction, very high currents can be measured before saturation is reached, thereby disturbing the linearity of the current mapping.
By fine tuning the ratio of silicon to boron and the ratio of Co, Fe, Mn to the remainder of the alloy, a particularly high saturation induction can be achieved. In this case, the saturation induction can be increased by increasing the proportion of the ferromagnetic elements Co and Fe, but also by Mn compared to the Gesamtmetalloidgehalt. In addition, due to its 4 valence electrons, Si decreases the magnetic moment more than B with only 3 valence electrons. In this way, by a favorable fine-tuning of B to Si, the saturation induction at a constant total metal oxide content can be further increased. However, the magnetostriction, which becomes more negative as the metalloid content decreases, must then be adjusted again via the Fe content to such an extent that the zero crossing can finally be achieved by the target temperature.

By fine tuning the iron content to manganese content can when choosing a suitable target temperature a Saturation magnetostriction can be achieved, the amount thereof is less than 0.1 or even 0.05 ppm. Because of the small Saturation magnetostriction is the one for uniaxial anisotropy Competing disturbance anisotropy particularly small. In order to can also be used for small uniaxial anisotropies A high permeability requirement is a good one Achieve linearity of the hysteresis loop.

Preferably, the magnetic core has no air gap. One Current transformer with a magnetic core without air gap has a particularly high immunity to external Foreign magnetic fields without additional shielding on. The magnetic core is for example a closed, air-gapless toroid, oval core or rectangular core. has the band, as in the case of the toroidal one Rotational symmetry axis, so is the anisotropy axis parallel to the rotational symmetry axis.

With regard to the eddy current losses and thus the course The permeability has proven to be a favorable area for the Tape thickness of the tape has a thickness d ≤ 26 microns proven. Around on the other hand a possible linear narrow hysteresis loop to reach, a band thickness d ≥ 15 microns has been found. at the alloys according to the invention can be characterized by the surface-related proportion of the disturbance anisotropies surprising strongly lower.

Especially small coercive field strengths and therefore one particularly good linearity of the hysteresis loop is achieved if the tape at least on a surface with a is provided electrically insulating layer. this causes on the one hand a better relaxation of the core, on the other hand can be through the electrically insulating layer as well achieve particularly low eddy current losses.

For example, the tape is wrapped at least before winding one of its two surfaces with the electric provided insulating layer. For this is depending on Requirement for the quality of the insulating layer, a dipping, Continuous flow, spray or electrolysis on strip used.

Alternatively, the wound magnetic core is heated before heating subjected the target temperature of a dip insulation, so that provided the tape with the electrically insulating layer becomes. Particularly advantageous is a dipping method exposed to negative pressure.

When choosing the insulating medium is on it too Make sure that this is good on the belt surface adheres, on the other hand causes no surface reaction, which can lead to damage to the magnetic properties. The alloys in question have oxides, Acrylates, phosphates, silicates and chromates of the elements Calcium, magnesium, aluminum, titanium, zirconium, hafnium, Silicon as an effective and compatible insulator exposed. Particularly effective is magnesium, which as a liquid magnesium-containing precursor to the Band surface is applied and during a special, not influencing the alloy Heat treatment in a dense magnesium-containing layer whose thickness D can be between 25 nm and 3 μm. At the temperatures of the above Magnetic field heat treatment then creates the actual Insulator layer of magnesium oxide.

The secondary winding of the current transformer can be a number of turns which is less than or equal to 2200. The Primary winding of the current transformer can be a number of turns which is equal to three. The current transformer can be used for be designed a primary current that is less than or equal to 20A is.

The heating to the target temperature takes place as possible fast. For example, the heating is carried out on the Target temperature at a rate between 1 to 15 K / min.

The magnetic core is for example between 0.25 and 4 Hours kept at the target temperature to one as possible good balance of mechanical stresses. This time can be shorter, the higher the Target temperature is.

The cooling between the relaxation temperature and the Curie temperature is also as fast as possible, e.g. at rates of 0.5 - 10 K / min. It regulates the cooling rate the proportion of the free volume and thus the atomic Alignment capability, which at lower temperatures to Adjustment of anisotropy is available. To Reaching the Curie temperature is in the applied field, the perpendicular to the direction of the belt, at 0.1 - 5 K / min cooled. This cooling rate is chosen so that under the driving force of the magnetic field through the atomic Reorientation a uniaxial anisotropy of the desired Size arises. Since this uniaxial anisotropy is reciprocal to Permeability is high with high cooling rates Adjust permeability.

However, to linearize the hysteresis loop or to Increase the anisotropic field strength a little higher magnetic field-induced uniaxial anisotropy may be below the Curie temperature stationary temperature plateau are inserted. The Temperature is to be chosen so low that the magnetic moments are as high as possible, but on the other hand so high that the kinetics of the alignment processes still runs fast enough. Depending on the effect, the length of the Temperature plateaus with applied magnetic field between 0.1 and 24 h.

To produce the magnetic core, for example, first an amorphous ribbon from a melt by itself known rapid solidification technology, for example, in DE 37 31 781 C1 is described. The amorphous Alloy tape is then tension-free to the magnetic core wound. It is to reduce the disturbance anisotropies Preferably to proceed so that the band a small Surface roughness has.

The heat treatment is carried out so that the value of the saturation magnetostriction λ _s during the heat treatment changes in the positive direction by an amount dependent on the alloy composition until it is in the range | λ _s | <0.5 ppm, preferably | λ _s | <0.05 ppm. This value can also be achieved if the amount of λ _s in the "as quenched" state of the strip, ie directly after the casting process, is significantly above this value.

Depending on the alloy used, a purging of the Magnetic core with a reducing or at least passive Shielding gas, so that at the belt surface neither Oxidations still other reactions can occur apart from the permissible in certain cases self-passivating and at the same time also electric insulating extremely thin metalloid oxide layers.

The magnetic core thus treated is finally solidified, e.g. by soaking, coating, wrapping with suitable Plastic materials and / or encapsulation and with each provided at least the secondary winding of the current transformer.

Figur 3

zeigt schematisch den Verlauf einer Wärmebehandlung eines Magnetkerns.

Figur 4

zeigt im Vergleich die Abhängigkeiten der Permeabilitäten des Magnetkerns und der Permeabilitäten von Permalloy-Kernen von einer Induktionsamplitude, die durch ein erregendes Magnetfeld erzeugt wird.

Figur 5

zeigt die Abhängigkeit des Amplitudenfehlers und des Phasenfehlers vom zu messenden Strom (Primärstrom).

Figur 6

zeigt schematisch den Magnetkern, der aus einem Band mit einer isolierenden Schicht besteht, und seine Anisotropieachse.

In the following, embodiments of the invention will be explained in more detail with reference to FIGS.

FIG. 3

schematically shows the course of a heat treatment of a magnetic core.

FIG. 4

shows in comparison the dependencies of the permeabilities of the magnetic core and the permeabilities of Permalloy cores of an induction amplitude, which is generated by an exciting magnetic field.

FIG. 5

shows the dependence of the amplitude error and the phase error on the current to be measured (primary current).

FIG. 6

schematically shows the magnetic core, which consists of a band with an insulating layer, and its anisotropy axis.

Figure 6 is not to scale and shows for better Clarity only a few turns.

With an only 3.3 g magnetic core M made of an amorphous ferromagnetic alloy of composition Co _67.7 Fe _3.8 Mo _1.5 Si _16.5 B _10.5 could be a current transformer with a primary turn number N ₁ = 3 and a secondary turn number N ₂ = 2000, which was terminated with a low resistance via a load resistance of 100 ohms in the secondary circuit.

For this purpose, the magnetic core M, the one with a 250nm thick insulating layer S of magnesium oxide coated band B, the one shown in Figure 3 Subjected to heat treatment. First, the magnetic core M at a rate of about 420 K / h within an hour heated to a target temperature of about 458 ° C and there about 1.5 h held. This was followed by a cooling at a rate from about 120 K / h within about two hours to about 220 ° C and at a rate of about 60 K / h within about three Hours to room temperature. Cooling at the rate of 60 K / h was done in a transverse magnetic field parallel to a rotational symmetry axis of the magnetic core M. there An anisotropy axis A formed parallel to the magnetic field along which the magnetization of the magnetic core M aligns particularly easily (see Figure 6).

In this example, the magnetostriction was reduced to the very low value of -1.2 * 10 ^-8 by the heat treatment of λ _s = -13.5 * 10 ^-8 . At the same time, the mechanical stresses previously existing in the wound magnetic core M were almost completely eliminated and thus the condition | σ | ≈0, where σ is the mechanical elastic stress tensor. This created the conditions for high permeabilities and indeed μ (50 Hz) = 177,000 was achieved. Thus, a favorable combination with high permeability and very good linearity (ie | λs | ≈0 and | σ | ≈0) was achieved.

The hysteresis loop was so linear that the modulation dependence of the permeability shown in FIG. 4 runs approximately constant. Comparable properties were also measured at target temperatures of T _σ = 449 ° C. For comparison, the modulation dependence of the permeability of conventional permalloy alloys is shown in FIG.

The measured after winding at the described current transformer Gradients of phase error φ and amplitude error F are in Figure 5 shown. The comparison shows Conventional permalloy alloys exemplify the Advantages of current transformers from magnetostriction-free highly permeable amorph cores.

The current transformer had a mean phase error φ of 0.19 ° and thereby a linearity of the phase angle Δφ over a current range of 0.1 to 2 A of less than 0.02 °. The permeability of this amorphous heat-treated ferromagnetic alloy is at a field amplitude H and of 4 mA / cm at 192000. The magnetic core M used is a ring tape core of dimensions 19 x 15 x 5 mm with an iron cross-section of A _Fe = 0.081 cm ² ,

Co_67,62Fe_3,7Mo_1,5Si_16,5B_10,68

Co_68,2Fe_3,9Mo_1,5Si_16,3B_10,1

Co_67,65Fe_3,4Mn_1,0Si_16,75Mo_0,2B_11,0

Co_68,3Fe_3,4Mn_1,0Si_16,5Mo_0,5B_10,3

Co_68,2Fe_4,1Ni_1,4Si_14,7C_0,2B_11,4.

Similarly good current transformers could be produced with magnetic cores made of the following alloys:

Co _67.62 Fe _3.7 Mo _1.5 Si _16.5 B _10.68

Co _68.2 Fe _3.9 Mo _1.5 Si _16.3 B _10.1

Co _67.65 Fe _3.4 Mn _1.0 Si _16.75 Mo _0.2 B _11.0

Co _68.3 Fe _3.4 Mn _1.0 Si _16.5 Mo _0.5 B _10.3

Co _68.2 Fe _4.1 Ni _1.4 Si _14.7 C _0.2 B _11.4 .

In contrast to these examples, using one of the alloys already described (the composition Co _67.7 Fe _3.8 Mo _1.5 Si _16.5 B _10.5 ), significantly poorer magnetic properties were achieved if the heat treatment was carried out in a different manner , In a first modification, with the intention of even better relaxation, the target temperature was increased to 510 ° C. However, the highly nonlinear hysteresis loop that occurs subsequently had an initial permeability of only 9,400 because of strong disruptive anisotropies due to the onset of crystallization.

On the other hand, when the relaxation was carried out at T _σ = 400 ° C, the linearity of the hysteresis loop also deteriorated, in which case the initial permeability was 97,000.

After a rapid cooling in the transverse field at 2.5 K / min instead of 1 K / min (see Figure 3) rounded the loop because of the now extremely small uniaxial anisotropy K _u also. The initial permeability was therefore only 127,000.

After a slow cooling in the transverse field at 0.5 K / min the loop kept its pronounced linearity. The bigger one However, uniaxial anisotropy energy also led to a reduced permeability of only 139,000.

Claims (20)

1. Use of a magnetic core for a current transformer,
   characterized in that the magnetic core

   comprises a wound strip (B) of an amorphous, ferromagnetic alloy,

   has a saturation permeability which is greater than 20,000 and less than 300,000,

   has a saturation magnetostriction of an absolute amount less than 0.5 ppm,

   is substantially free from mechanical stress,

   has an anisotropy axis (A) along which the magnetization of the magnetic core (M) is aligned particularly easily and is perpendicular to a plane in which a centre line of the strip (B) runs, and

   the alloy has a composition which substantially comprises the formula Co_a(Fe_1-xMn_x)_bNi_cX_dSi_eB_fC_g,

   where X is at least one of the elements V, Nb, Ta, Cr, Mo, W, Ge, P, a to g are given in atomic % and a, b, c, d, e, f, g and x satisfy the following conditions: 40 ≤ a ≤ 82; 3 ≤ b ≤ 10; 0 ≤ c ≤ 30; 0 ≤ d ≤ 5; 0 ≤ e ≤ 20; 7 ≤ f ≤ 26; 0 ≤ g ≤ 3; with 15 ≤ d + e + f + g ≤ 33 and 0 ≤ x ≤ 1.
2. Use according to Claim 1, characterized in that a, b, c, d , e, f, g and x satisfy the following conditions: 63 ≤ a ≤ 73, 3 ≤ b ≤ 10; 0 ≤ c ≤ 5; 0 ≤ d ≤ 3; 12 ≤ e ≤ 19; 8 ≤ f ≤ 20; 0 ≤ g ≤ 3; with 20 ≤ d + e + f + g ≤ 30 and x ≤ 0.5
3. Use according to Claim 2, characterized in that a, b and c satisfy the following conditions: 68 ≤ a + b + c ≤ 75.
4. Use according to Claim 3, characterized in that the absolute amount of the saturation magnetostriction is less than 0.1 ppm.
5. Use according to one of Claims 1 to 4,
   characterized in that the magnetic core (M) ha s a saturation magnetization B_s of 0.5 to 0.7 T.
6. Use according to one of Claims 1 5, characterized in that the strip (B) has a thickness d of 15 µm ≤ d ≤ 26 µm.
7. Use according to one of Claims 1 to 6,
   characterized in that the strip (B) is provided at least on one surface with an electrically insulating layer (S).
8. Use according to Claim 7, characterized in that a layer of magnesium oxide is provided as the electrically insulating layer (S).
9. Use according to Claim 8, characterized in that the electrically insulating layer (S) has a thickness D of 25 nm ≤ D ≤ 1 µm.
10. Use according to one of Claims 1 to 9,
    characterized in that it is designed as a closed, air-gap-less toroidal core, oval core or rectangular core.
11. Use according to one of C laims 1 to 11,
    characterized in that the ratio of its mechanical elastic stress tensor multiplied by the saturation magnetostriction to its uniaxial anisotropy is less than 0.5.
12. Current transformer for alternating current with a magnetic core according to one of Claims 1 to 11, the current transformer comprising in addition to the magnetic core (M) as the transformer core at least one primary winding and at least one secondary winding, parallel to which a loading resistor is connected and which provides the secondary circuit with a low-resistance termination.
13. Current transformer according to Claim 12,
    characterized in that the secondary winding has a number of turns N _sec ≤ 2200, the primary winding having a number of turns N _prim = 3 and the current transformer being designed for a primary current I_prim < 20 A.
14. Method for producing a magnetic core according to one of Claims 1 to 11,

    in which, after producing and winding the strip (B) to form the magnetic core (M), the magnetic core (M) is heated to a target temperature between 380°C and 500°C,

    in which the magnetic core (M) is cooled from the target temperature to room temperature, a magnetic field of H > 100 A/cm, which is parallel to the anisotropy axis (A) of the magnetic core (M) being switch ed on the latest from the Curie temperature of the alloy,

    in which the rate of cooling from the Curie temperature to room temperature lies between 0.1 and 5 K/min.
15. Method according to Claim 14,

    in which the heating to the target temperature takes place at a rate between 1 and 15 K/min,

    in which the magnetic core (M) is kept at the target temperature between 0.25 and 4 hours.
16. Method according to Claim 14 or 15,

    in which the cooling is interrupted at an intermediate temperature, which lies below the Curie temperature and at which the magnetic core (M) is kept between 0.1 and 24 hours.
17. Method according to one of Claims 14 to 16,

    in which the cooling takes place at rates between 0.1 and 15 K/min.
18. Method according to Claim 17,

    in which the coo ling to the Curie temperature takes place at a rate between 0.5 and 10 K/min.
19. Method according to one of Claims 14 to 18,

    in which, before the winding, the strip (B) is provided with an electrically insulating layer (S) on at least one of its two surfaces.
20. Method according to one of Claims 14 to 18,

    in which, before heating to the target temperature, the magnetic core (M) is subjected to an immersion insulation , so that the strip (B) is provided with an electrically insulating layer (S).

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