DE4019636A1 - METHOD FOR IMPROVING THE MAGNETIC PROPERTIES BY APPLYING AC OR PULSED CURRENT - Google Patents

Description

The invention relates to a method for improving the magnetic properties of magnetic material and especially a method to improve magnetic Properties of ferromagnetic amorphous alloys Apply alternating current or pulsed current.

Ferromagnetic amorphous alloys are often used for many magnetic applications such as distribution transformers, direct current sources, motors, current amplifiers, magnetic shields etc. used. Amorphous iron base alloys show after Annealing in conventional furnaces is an embrittlement. That represents for many applications pose a serious problem.

Efforts have been made in the past to a new magnetic material with better magnetic Properties such as higher magnetic induction (Bm), lower ones Coercive force (Hc) and therefore less core loss when the Transformer core made of such materials can be found. For ferromagnetic materials that have been used in the past Manufacturing transformer cores have been used, it is very difficult to operate their magnetic properties to change.

It is therefore the object of the present invention to provide a method to improve the magnetic properties of ferromagne tables to create amorphous alloys.

An essential feature of the present invention is the step the use of alternating current or pulsed current during the Magnetization of the ferromagnetic amorphous  Alloys to increase the maximum value of the magnetic Induction (Bm) and reduction of the minimum value of the coercive field strength (Hc).

The AC power is taken from an AC power source and via a pair of electrodes directly into the ferromagnetic part Material directed. It is believed that by the ferromagnetic material flowing current in the domain wall Material shifts depending on the current density and Frequency. Therefore, the soft magnetic properties of the improved ferromagnetic material. The procedure of The present invention further includes the step of applying AC or pulsed current on a sample from a Alloy made with AC resistance heating or pulsed high current has been heat treated. This amorphous Alloy does not become brittle during the annealing process demonstrate. The AC resistance heating or the pulsed High current process to improve the magnetic properties and the embrittlement of the alloy is in pending US patent Application 3 38 895 from April 14, 1989.

The applied alternating current or pulsed current has a frequency in the range of 50 to 50,000 Hz and a current density of 10 to 500 A / cm² and a sine, triangle or square waveform.

Accordingly, the method for improving the magnetic properties of ferromagnetic amorphous alloys according to the present invention a first step in creation a ferromagnetic amorphous alloy part in one Magnetizing field, a second step is the application of AC or pulsed current that is passed through the part and in a third step the acquisition and recording of the magnetic induction and coercive force of the part during  of magnetization and demagnetization.

These and other advantages, tasks and features of the process According to the present invention, the following detailed description of preferred embodiments with Clarified with reference to the drawing.

Fig. 1 is a schematic diagram of the system for measuring the BH loop of a straight part according to the method according to the invention.

Fig. 2 is a schematic diagram of a system for measuring the BH loop of an annular part according to the method of the invention.

Fig. 3 is a perspective view of a ferromagnetic amorphous alloy ribbon having its magnetic domain structure.

Fig. 4 is a diagram showing the dependence of the magnetic induction and coercive force of a straight Fe₇₈B₁₃Si₉ sample through which a 60 Hz sinusoidal current flows.

Fig. 5 is a diagram showing the change in magnetic induction and coercive force of a straight Fe₇₈B₁₃Si₉ sample with an alternating current with different frequencies.

Fig. 6 is a diagram with a BH loop for a straight Fe₇₈B₁₃Si₉ sample in the cast state after an AC resistance heat and when using AC.

The process for improving the magnetic properties ferromagnetic amorphous alloy using high AC or pulsed current is through the following Clarification clarified.  

1. Samples

Ferromagnetic amorphous bands of different compositions, especially iron or nickel based amorphous ribbons. Is too it suitable for all crystalline materials.

Sample shape - straight long bands,
- toroid wound from a long band,
- C-shaped, E-shaped or right-angled core type.

In the experiments, samples of the composition Fe₇₈B₁₃Si₉ used and brought into a straight and annular shape.

2. Measure the magnetic properties with alternating or pulsed current flowing through the samples A. Straight samples

The straight samples were uniform in the center Magnetic field (H) brought by a long solenoid coil was generated, which to a bipolar direct current source or a function generator was connected. Both ends of the straight amorphous band were made by two square copper plates clamped, which were connected to the output connections an AC power source capable of generating a search coil (S) combined with a compensation coil (C) and which is connected to a flux meter (or integrator) for Measurement of the magnetic flux density (B) of the sample. By connecting the connections of the applied magnetic field (H) and the magnetic flux density (B) using an X-Y recorder B-H hysteresis loop received.

B. Ring samples

The ring samples were made by winding a long amorphous tape coated with insulation materials. The two ends of the long band were connected to the output of the AC power source. The toroid was wound from two coils, the primary coil (N₁) was connected to the bipolar DC power source or a function generator to generate the applied magnetic field (H), and the secondary coil (N₂) was connected to a flux meter or integrator to the to measure magnetic flux density (B). Then the BH hysteresis loop was obtained by connecting the connection points of H and B to an XY recorder ( Fig. 2).

3. Conditions of the AC current applied through the samples

Frequency range: 50 Hz to 5 kHz
Waveform: sine wave, triangular or rectangular wave,
Current density: J = 10-500 A / cm².

Cross-field induced by alternating current or pulsed current.

Except near the band edges, the magnetic field generated by applying a current I through a rectangular sample is substantially transverse and varies linearly with the distance from the plane of the band center. Fig. 3 shows the cross section of the amorphous band and its possible magnetic domain structure.

4. Examples of improvements to the different types of ferro magnetic amorphous alloys as a result of the process according to the invention by applying alternating current, which through which samples of ferromagnetic material flow Example 1

Sample: straight shape (15, 24 cm × 3.05 mm × 25 µm)
Composition: Fe₇₈B₁₃Si₉
Reference magnet properties of the cast samples:
When applying a magnetic field: Hm = ± 0.296 Oe
a. Magnetic induction: Bm₀ = 7.16 kG
b. Coercive force: Hc₀ = 0.074 Oe

Effects of magnetic properties under alternating current Samples:

A. Dependency on AC density

When a current of a 60 Hz sine curve flows through the samples with different current densities J = 0 to 334 A / cm² (I = 0 to 250 mA), there are changes in the magnetic induction and coercive force of the samples according to FIG. 4. The magnetic Induction values under different current densities are almost the same and slightly higher than the value of cast samples. However, the coercive force of the samples decreases noticeably as the current density increases. The decrease is slower after the current density is higher than 150 A / cm². When the current density is 334 A / cm², the coercive force becomes lower than half the value of a cast sample.

B. Frequency dependence

When the samples carried the same alternating current (current density J = 160 A / cm²) with different frequencies (50 Hz-20 kHz), the changes in the magnetic induction and coercive force of the samples were as shown in Fig. 5. So the magnetic induction is almost the same and somewhat higher than the value of the cast sample. The values of the coercive force ratio are around 0.5 and the minimum is in the frequency range from 100 to 1000 Hz.

C. Waveform Dependency

The waveform of the alternating current that can flow through the samples Have a sine, triangle or rectangular shape. Under the same Peak current is the effect of improving the magnetic Properties best with square waves, and the effects with Sinusoidal and triangular are almost the same. For 300 Hz current through the samples is the change in magnetic induction and Coercive field strength with an applied magnetic field Hm = +0.296 Oe according to the following list:  

Example 2

Sample: circular
Composition: Fe₇₈B₁₃Si₉

A 5-layer amorphous core with a diameter of 3.8 cm was wound from a 60 cm long band (width: 7.5 cm, Thickness 25 µm, weight: 6.623 g).

The reference magnet properties of the cast sample:
When applying a magnetic field when measuring the BH loop Hm = ± 0.15 Oe
a. magnetic induction Bm₀ = 6.71 kG
b. Coercive field strength Hc₀ = 0.073 Oe

Create a 60 Hz sine curve through the core. The improved magnetic induction and coercivity of the samples as follows:

Example 3

Sample: straight shape (15 cm × 3.05 mm × 25 µm)
Composition: Fe₇₈B₁₃Si₉

A. Cast sample
Magnetic field applied when measuring the BH loop Hm = +0.292 Oe
- Magnetic induction Bm = 7.07 kG
- Coercive field strength Hc = 0.075 Oe

B. After AC resistance heating with
- frequency f = 60 Hz
- Current density J = 3000 A / cm²
- heating time t _h = 50 s
- Created field Hp = 100 Oe
Magnetic field when measuring the BH loop Hm = ± 0.292 Oe
- Magnetic induction Bm = 9.70 kG
- Coercive field strength Hc = 0.04 Oe
Breaking stress ε _f = 1 (ductility)

C. AC through the samples after AC resistance heating with
- Frequency: f = 300 Hz
- Waveform: rectangle
- Current density: 160 A / cm²
Magnetic field Hm = ± 0.292 Oe applied when measuring the BH loop
- Magnetic induction Bm = 9.89 kG
- Coercive field strength Hc = 0.017 Oe

The BH loops of the cast samples, the samples after AC resistance heating, and those of the samples through which AC current is flowing are shown in FIG .

Claims (9)

1. A method for improving the magnetic properties of ferromagnetic materials, characterized in that

• (a) brought a part made of ferromagnetic material into a magnetizing and demagnetizing field and
• (b) an alternating current is passed through the part.

2. The method according to claim 1, characterized in that the improved magnetic properties of the part are recorded. 3. The method according to claim 2, characterized in that the magnetic Induction and the coercive force of the parts determined and to be recorded. 4. The method according to claim 1, characterized in that for the parts ferromagnetic amorphous alloys are used. 5. The method according to claim 4, characterized in that parts from an amorphous iron, nickel or cobalt based alloy is used. 6. The method according to claim 1, characterized in that an alternating current applied with a frequency in the range of 50 to 50,000 Hz becomes.   7. The method according to claim 1, characterized in that the applied AC has a sinusoidal, triangular or rectangular shape. 8. The method according to claim 1, characterized in that the alternating current is used with a current density of 10 to 500 A / cm². 9. The method according to claim 1, characterized in that parts with a straight shape of a ring shape or any transformer core shape be used.