DE2920084A1 - Pulse generator for interrogating by magnetisation change - detects position of rotating magnet using sensor coil around amorphous soft-magnetic alloy - Google Patents

Abstract

The pulse generator consists of a wire or tape like piece (24) of amorphous soft-magnetic alloy and a sensor coil (23). The sensor coil encircles the amorphous alloy wire or tape like piece. The alloy has a magnetostriction of 0 (+-) 2.10-6 or alternatively of an alloy with positive magnetostriction when under tension. The generator has a speed generator with rotating permanent magnet (21) whose position is detected by the sensor coil/alloy piece. The pulse generator is encircled by an excitation coil and can move relative to a permanent magnet. The generator may be used as a position or rotational speed sensor.

Description

Pulse generator for querying through magnetic reversal

The invention relates to a pulse generator for interrogation by magnetic reversal.

It is known to generate high voltage pulses due to rapid magnetization reversal crystalline soft magnetic materials with a rectangular hysteresis loop to create. The height of the voltage pulse is proportional to the time Change in magnetic flux. So far, crystalline ones have been used for this purpose Metal alloys based on nickel-iron with 45 to 81 ffi nickel or based on cobalt-iron with about 50 ffi cobalt. The rectangular loop is in these in the form of thin The materials present in strips either through the choice of alloy components (magnetostriction X in the preferred direction towards zero), through crystallographic textures and / or through suitable heat treatments, for example in a magnetic field. The disadvantage, however, is the high sensitivity of these materials to one Deformation after setting the magnetic properties by means of a heat treatment proven. Even slight deformations of the finally annealed thin strips or the from these wound tape cores can cause considerable damage to the magnetic properties lead.

The object of the invention is to provide a pulse generator for the query Indicate reversal of magnetization from a relatively insensitive to deformation Material.

This is according to the invention in a pulse generator of the type mentioned at the outset achieved in that it consists of a wire or band-shaped piece of a amorphous soft magnetic alloy and a sensor coil.

If the pulse generator is stationary or only within a distance that can be bridged by supply lines, the wire or ribbon-shaped piece made of an amorphous soft magnetic alloy advantageous from be surrounded by the sensor coil.

Amorphous soft magnetic alloys in the form of thin wires or Tapes are known to be relatively insensitive materials to the effects of deformation. Furthermore, amorphous, soft magnetic alloys already have largely due to their production rectangular hysteresis loops. Their yield strength is so high that they are much more insensitive to the effects of deformation and thus to a Damage to their magnetic properties are called crystalline soft magnetic Materials. Investigations have now shown the excellent suitability of amorphous soft magnetic alloys for pulse generators can be determined.

The rectangular shape of the hysteresis loop is particularly pronounced in the case of amorphous soft magnetic alloys with low magnetostriction (cf. Example DE-OS 25 46 676).

For pulse generators for interrogation by magnetization reversal can be preferred in particular amorphous soft magnetic alloys are t whose magnetostriction 0 # 2, the magnetostriction of which is 0 t 2 10, i.e. i.e., their magnetostriction values lie in the range from -2 io6 to +2 106. For example, alloys with the Composition Co70Fe5Sil5B1O or (Co Fe Ni) 78Si8B14 an almost negligible Magnetostriction on. The pulse generator can, however, also be made up of one under Tensile stress amorphous soft magnetic alloy with positive magnetostriction exist.

The pulse generator according to the invention can advantageously be used as sensor elements can be used, for example, for position, speed and position sensors. at this application is a direct activation of logic elements of control or Control systems possible.

As is known, amorphous alloys can be produced by that one cools a melt of the corresponding composition so quickly that a Solidification occurs without recrystallization. The alloys become the same obtained in their formation in the form of thin ribbons, their thickness, for example a few hundredths of a millimeter and their width, for example, a few millimeters can be up to several centimeters. Depending on the manufacturing conditions, you can the amorphous alloys can be completely or partially amorphous.

In general, an alloy is called an amorphous alloy, when the amorphous part predominates. The composition of the previously known amorphous Soft magnetic alloys can be obtained with the general formula TrM1oo y described where T is at least one of the transition metals such as iron, cobalt or nickel and M at least one of the crystallization retarding metalloid elements such as Means carbon, boron, silicon or phosphorus and y is usually between 60 and 95 lies. In addition to the metals labeled T, the amorphous Alloys also other metals, in particular Ti, Zr, Hf, V, Nb, Ta, Cr, Mo, W, Mn, Pd, Pt, Cu, Ag or Au contain, while in addition to the metalloid elements M or, if appropriate, instead of these, the elements Al, Ga, In, Ge, Sn, As, Sb, Bi or Be can be present. The alloys mentioned can already have so favorable soft magnetic properties after their production that In general, no magnetic field tempering for setting a rectangular loop more is required. In many cases, however, the soft magnetic properties can also be used of the materials mentioned by one below the crystallization temperature and heat treatment carried out below the Curie temperature, for example in one magnetic longitudinal field, can be further improved.

The invention is intended to be based on a few figures and exemplary embodiments will be explained in more detail.

Figure 1 shows schematically a measuring arrangement for determining the amplitude, the form and the instant of onset of the voltage pulse signal in the case of a Impulse generator.

Figures 2 A and 2 B show schematically a speed sensor using a pulse generator according to the application.

Figures 3 A to D and 4 A to D show schematically position transmitter using a pulse generator according to the application and associated pulse diagrams.

The impulse measurements on wire or ribbon-shaped pieces from amorphous soft magnetic alloys were made with the aid of the ones shown in FIG Measurement arrangement carried out. A sample piece 11 approximately 75 mm long, for example made of an amorphous soft magnetic alloy with the composition Co71Fe5S i8B16, was arranged within an approximately 15 - long sensor coil 12 with 1000 turns, which in turn is located within a 60 mm long excitation coil 13 with 120 turns found. A structure with an excitation coil also served as the compensation coil 16 and a sensor coil 15 arranged within it. Both excitation coils 13 and 16 were connected in series and connected to an AC voltage source 14, which allowed the frequency of the exciting sinusoidal field, for example to be set to 0.1 or 1 kHz. The two sensor coils 12 and 15 were to an oscilloscope 17 for measuring the height and duration of the voltage pulse signal connected.

The results of the investigations on various amorphous soft magnetic Alloys are summarized in Tables 1 and II. In Table I are in the individual columns the sample numbers, the composition of the various amorphous soft magnetic alloys and their magnetostriction values are given. In Table II is the results of the tests on those listed in Table I. Alloys summarized. In the first column there are those corresponding to Table I. Frost numbers indicated. The examined amorphous soft magnetic alloys with positive magnetostriction lay in the form of thin ribbons with a thickness of about 0.04 nm and a width of about 1.1 mm. The exact cross-section Qpe of the test samples is given in column 2.

The following measured values are listed in the other columns: the Frequency f of the exciting sinusoidal field (0.1 or 1 kHz), the Current flowing through the excitation and compensation coil in A, the amplitude H. the magnetic field strength H in A / cm, the voltage pulses U in V, 5 those at the Magnetization reversal occurred, the relative U voltage pulses Us / qFe, eventually nor the total duration #t and the rise time # t of the pulse signal, which is the duration until the pulse maximum is reached.

Table I Sample No. Composition magnetostriction # 1 Fe60Ni21B19 + 20. 10-6 2 Fe40Ni40P14B6 + 11. 10-6 3 Co71Fe8 Si4B17 + 2. 10 66 4 C071Fe5Si8B16 + 0.1. 10-6 Table II Samples- qFe f i H Us Us / qFe #t #t s Fe No. mm2 kllz A A / cm V / mm2 µs 1 0.060 0.1 2 40 2.5 42 50 30 1.0 0.2 4 2.8 47 50 30 2 0.044 0.1 2 40 1.7 39 30 20 1.0 0.2 4 2.0 45 30 20 3 0.040 0.1 2 40 3.0 75 30 8 1.0 0.2 4 4.0 100 25 10 4 0.035 0.1 2 40 3o0 86 25 20 1.0 0.2 4 4.2 120 20 15 From table I in conjunction with Table II can be seen that in particular by amorphous soft magnetic alloys with vanishing magnetostriction (for example Alloy sample 4) allow relatively high voltage pulse signals to be obtained. So is for example in the case of alloy sample 4 excited with a sinusoidal field of 1 kHz, a relative A voltage pulse signal of 120 V / mm2 has been measured.

This value is more than a factor of 2 greater than the corresponding one Signal from alloy 2, the magnetostriction of which is 11 106. It should be emphasized also that when using amorphous soft magnetic alloys with lower Magnetostriction, preferably of those with a magnetostriction of 0 + 2 10 10-6, both the total pulse duration of the voltage signal and the duration of the Voltage pulse until it reaches the maximum (pulse rise time) are shorter and thus the remagnetization takes place faster than with amorphous alloys with a magnetostriction very strongly deviating from zero.

Figures 2 A and 2 B show a preferred form of application of the Pulse generator according to the invention in a tachometer with rotating permanent magnet. A permanent magnet body 21, for example a cuboid piece from a Cobalt-samarium alloy, attached to the periphery of a rotating disc 22, for example glued on. If the permanent magnet body 21 now rotates on a pulse generator over, which consists of a strip element 24 surrounded by a sensor coil 23 of a amorphous soft magnetic alloy, the strip element 24 is briefly magnetized and a pulse voltage is created at the ends of the sensor coil winding, the duration and height of which depend on the size of the panel. From a certain point Minimum speed of the rotating disk 22 can with the help the arrangement shown in Figure 2, the speed, for example of a motor or a quantity counter.

In addition to the magnetic reversal of the strip element by approaching it a suitable permanent magnet body, this can also be done by a current-carrying Excitation coil be ummagne + ized. In Figures 3 and 4 are schematically more Application forms of the pulse generator shown, for example for a position transmitter can be used. The pulse generator is here, as in FIGS. 3 A and 3 C shown, additionally surrounded by an excitation coil 33 and relative to a permanent magnet body 34 movable. The strip member 31 is made of the amorphous soft magnetic alloy The sensor coil is excited with a sinusoidal field strength and sufficiently high amplitude 32 positive and negative voltage pulses. The course of the signal over time the sensor coil is depending on the position of the permanent magnet body 34 in Figures 3 B and 3 D shown. If a permanent magnet body 34 of this arrangement is now approached, how This is shown schematically in Figure 3C, the strip element 31 becomes magnetic saturated and the sensor coil 32 can no longer emit any pulses (FIG. 3 D).

A modification of the pulse generator according to FIG. 3 is shown in FIG A and 4C shown. The pulse generator is in turn surrounded by an excitation coil 43. A suitable permanent magnet body 44 is arranged adjacent to this, and this Arrangement then relative to an insertable between permanent magnet body 44 and pulse generator magnetic shield 45 is movable. With the shield 45 and Excitation with a sinusoidal field of 1 kHz is shown schematically in FIG. 4 D shown temporal course of the pulse signal.

Without the shield 45, the strip element 41 is magnetically saturated and the sensor coil 42 cannot emit a signal (FIG. 4 B).

The pulse generator according to the invention is suitable except for those shown Use cases, for example, for coding systems in which cards, the strips made of amorphous alloys, with a defined speed with motor drive be moved past a reading head containing the sensor coil.

Claims (7)

Patent claims cy pulse generator for querying through magnetic reversal, d u r c h e k e n n n z e i c h n e t that he is made of a wire or band-shaped piece (24) of an amorphous soft magnetic alloy and a sensor coil (23) exists. 2. Pulse generator according to claim 1, d a d u r c h g e k e n n -z e i c h n e t that the sensor coil (23) is the wire or band-shaped piece (24) made of an amorphous soft magnetic alloy surrounds. 3. Pulse generator according to claim 1 or 2, d a d u r c h g e -k e n n notices that it is made of a soft magnetic alloy with magnetostriction 0 # 2 10-6 exists. 4. Pulse generator according to claim 1 or 2, d a d u r c h g e -k e n n z e i n e t that it consists of a magnetically soft one under tensile stress Alloy with positive magnetostriction exists. 5. Use of a pulse generator according to one of claims 1 to 4 in the case of a speed sensor with a rotating permanent magnet (21). 6. Use of a pulse generator according to one of claims 1 to 4, for a position transmitter, in which the pulse transmitter is also supplied by an excitation coil (33) and is movable relative to a permanent magnet (34). 7. Use of a pulse generator according to one of claims 1 to 4 for a position transmitter in which the pulse transmitter is also supplied by an excitation coil (43) and adjacent to it a permanent magnet (44) is arranged and this Arrangement relative to one that can be inserted between the permanent magnet (44) and the pulse generator magnetic shield (45) is movable.