DE3844837C2 - Composite body producing impulse voltages for use in security wire - Google Patents

Abstract

Composite body for producing impulse voltage consists of a core and sheath of two magnetic materials of different coercivity which are mechanically stressed by heat treating. The sheath is a hard magnetic alloy in wt.% contg. 48-52 Co; 4-14 V; balance Fe or 21-30 Cr; 4-23 Co; 0-3 Mo; 0-1.5 Si; balance Fe and the core is a soft magnetic alloy containing 55-82 Ni; 0-4 Mo; balance Fe. The stress is induced by heating to 500-900 deg.C

Description

The invention relates to a composite body for production of voltage pulses consisting of a core and a shell made of two magnetic materials with different Coercive force exists in the case of the core and the shell by means of a Heat treatment are mechanically braced against each other and in which the soft magnetic part is made of an Fe alloy and the hard magnetic part from a Co-V-Fe or a Co-Cr-Fe alloy.

Such a composite body is in DE-PS 31 52 008 described. This composite body contains a core and an envelope whose materials are made of magnetic materials with different coercive field strength. For the magnetically harder material becomes, for example Alloy in the range of 45 to 55% by weight cobalt, 30 to 50% by weight iron and 4 to 14% by weight (chromium + vanadium) used while as a soft magnetic material in particular nickel is provided. Texture materials continue to be used as suitable soft magnetic materials from Fe-Ni, Fe-Co, Bi-Co or Fe-Ni-Co alloys.

This known composite body lies as an elongated one magnetic switch core.

It is also known from DE-OS 29 33 337, a composite body consisting of nickel or unalloyed Steel as a bracing component and a cobalt vanadi um-iron alloy as a magnetically active switching component to use for alarm systems. As from page 3 of the Be spelling is shown here by the iron-cobalt Vanadium alloy has a high coercive field strength Switching component aimed to be insensitive to Interference fields. This requires one in alarm systems  high query field strength and thus limits the possible Applications. In addition, this well-known composite body cannot be deactivated by magnetic interference.

An elongated composite body with a low An Speech field strength of 1.0 Oe (about 0.8 A / cm) is also in U.S. Patent 4,660,025 (Humphrey). For example, an elongated, 7.6 cm long wire made of amorphous material and it is indicated that the length of this wire is between 2.5 and Can be 10 cm.

With this known security strip, everyone can However, short lengths of the stripe only when extraordinary Realize thin strip cross-section, which in turn ei has a very low output pulse. The reason for this lies in the fact that the shear caused by the short Strip lengths relatively large in relation to the diameter Demagnetizing field causes insufficient Barkhausen jump and therefore not a sufficient sudden Magnetic reversal occurs more. This amorphous too Security strips cannot be deactivated magnetically.

Very small diameters of these wires have that Disadvantage that, for example, when used for theft security strip even a very slight change in alternating field used to trigger alarm, so that correspondingly sensitive measuring equipment or larger Lengths of the measuring strips become necessary.

In contrast, the task is to create a deactivable Ver specify federal body, especially for theft-proof is suitable and with a relatively large out gangsimpuls with a very short stripe length.  

This is achieved in that the core of the composite body of a soft magnetic alloy with the Composition in% by weight: 5-16 Al, balance including Fe melting-related impurities and the coat from one of hard magnetic alloys, their combination settlement in the case of the Co-V-Fe alloy in the range of 48-52 Co, 4-8 V, balance Fe including melt-related Impurities and in the case of the Co-Cr-Fe alloy 21-30 Cr, 4-23 Co, 0-3 Mo, 0-1.5 Si, balance iron one finally there is contamination from the melt, and that the wire for mechanical tensioning of the core and Shell exposed to a temperature of 500 to 700 ° C becomes.

This structure has the advantage that you can use a wire a coat of high strength and that you get relative can provide short wires. The dimensions are like this chosen that with demagnetized permanent magnet material, demagnetized hard magnetic shell, that relative large demagnetizing field despite the tension of the soft magnetic core any sudden magnetic reversal prevented.

By magnetizing the hard magnetic jacket ver however, the magnetization characteristic shifts so that due to the flow in the magnetically hard shell Demagneti zones largely avoided at the edge of the strip with the consequence that it is here with the magnetization comes in one direction to a Barkhaus jump while this in the case of magnetic reversal in the other direction is missing.

This property that the Barkhausensprung only when changes tion of the interrogating magnetic field in one direction occurs, especially for the use of theft security strips additionally the advantage that a special differentiation between the composite body and others  magnetic materials that can be taken are in the query zone and also the query Could influence magnetic field.

Further explanations on the manufacture and functioning of the composite wire are in the parent application (DE 38 24 075.0 C1) - to which reference is hereby made becomes hard - to find for composite wires with the same magnetic components and a soft magnetic Ni-Fe alloy.

You get a very low response field strength, if instead of a nickel-iron alloy chooses an aluminum-iron alloy according to the invention. If you have the Aluminum content in weight% changed between 5 and 16%, then you get a very soft magnetic and im Expansion behavior also above the expansion coefficients of the hard magnetic alloys used lying material. Such composite bodies even result even lower response field strengths than that in the The parent application described nickel-iron alloys.

Advantageous configurations are in the subclaims described. In particular, the cross-sectional ratio the hard magnetic shell to the soft magnetic core greater than 0.8 times the ratio of remanence induction of the soft magnetic core material for Remanent induction of the hard magnetic casing material.

When used as an activated anti-theft device stripes, the length should not be more than 50 mm. The length of the composite body is advantageously such chosen that the panel strength at which the Barkhausen jump takes place in the area between half the saturation strength of the demagnetizing field up to 2 times the saturation field strength of the demagnetizing Field.  

According to a special embodiment, the composite is wire characterized in that by the cross section ratio of hard magnetic jacket and soft magnetic the core depending on their remanence the switching field strength at which the Barkhausen jump takes place, is a maximum of 5 A / cm.

In particular, the cross section of the hard magnetic Mantels in connection with its remanence in the magnet Based state chosen so that the composite body a jumping field strength Hs between 1 and 2 A / cm results.

Figs. 1 and 2 show in comparison with the relationships between the given by the length and the diameter of the strip substantially demagnetization field strength relative to the coercive force. Here the demagnetization field strength is designated with He and the coercive field strength with H0, while the jump field strength at which the Barkhausen jump takes place is indicated with Hs. Is plotted in Figs. 1 and 2 respectively, the induction of Jw of the soft magnetic material relative to the field strength H.

The thin solid curves represent the magnetization with demagnetized permanent magnet material, so demagnetized shell, while the thickly extended Curves apply in the case of a magnetized shell are. The thin, dashed line shows the course of the Hysteresis loop as it is with a magnetized shell without strain of the core would result and the thick dashed line indicates the field strength Hs at the Barkhausen jump takes place.

In Fig. 1 it is assumed that the difference between switching field strength Hs and the coercive field strength H0 is greater than twice the amount of the demagnetizing field strength He. The field strengths H0 + He in the case of demagnetized sheath and H0 + 2 _* He in the case of magnetized sheath are entered as dash-dotted lines in FIG. 6, as the correspondingly designated arrows He and 2 _* He show. It can be seen that the thick dashed line at the switching field strength Hs is to the right of the dash-dotted line 2 _* He, so that the length-diameter ratio for the given impulse wire could still be changed in the direction of a thicker diameter or a shorter length without the resulting impulse triggered by the Bark jump is reduced.

Fig. 2 shows the same conditions for a wire with a shorter length or a larger diameter, in which the length-diameter ratio has been optimized to such an extent that a sufficiently large voltage pulse is still present with the shortest possible length. The thick dashed line for identifying the switching field strength Hs has a distance from the coercive field strength with a magnetized sleeve a distance from half the demagnetizing field strength, which is indicated by the arrow He / 2. The Barkhausensprung is still about 25% of the total induction stroke and it has been shown that this results in a sufficient measure for use in anti-theft systems. From this one receives the teaching that the length of the wire in relation to the diameter can be chosen in given material components so that the switching field strength is at least half the demagnetization field strength above the coercive force at magnetized sheath.

All described composite bodies have because of the short Length in relation to the cross section no jump function for remagnetization when the outer hard magnetic Coat is not magnetized. You are therefore inactive fourbar by demagnetizing the hard magnetic man tels. The demagnetization can, for example, with a  simple strong magnets can be done when one the magnetic field of this magnet perpendicular to the longitudinal direction of the composite body can act. By applying this De Activation method does not require an abclin alternating magnetic field in the longitudinal direction of the composite body pers to use.

The composite body according to the invention can be because of the gu th deformability of the materials also by rolling the first produce the composite body in wire form len. The tape shape has the advantage that the Composite body much less sensitive to crumbs is and therefore also for flexible labels from thief steel security systems can be used particularly well can.

Claims (8)

1. Composite body, which consists of a core and a shell made of two different magnetic materials, one of which is soft magnetic and the other is hard magnetic, in which the core and shell are mechanically braced against one another by heat treatment, and in which the soft magnetic part is made of a Fe alloy and the hard magnetic part of a Co-V-Fe or a Co-Cr-Fe alloy, characterized in that the core of the composite body made of a soft magnetic alloy with the composition in wt .-%: 5 -16 Al, rest Fe including melt-related impurities and the jacket consists of one of the hard magnetic alloys, the composition of which in the case of the Co-V-Fe alloy is in the range of 48-52 Co, 4-8 V, rest Fe including melt-related impurities and in the case of the Co-Cr-Fe alloy is made of 21-30 Cr, 4-23 Co, 0-3 Mo, 0-1.5 Si, balance iron including melting-related impurities, and that the wire exposed to a temperature of 500 to 700 ° C for mechanical tensioning of the core and shell. 2. Composite body according to claim 1, characterized in that the cross-sectional ratio of the hard magnetic shell to the soft magnetic core greater than 0.8 times the Ratio of the remanent induction of the soft magnetic Core material for the remanence induction of the hard magnetic Shell material is. 3. Composite body according to claim 1, characterized in that he ver as an activatable anti-theft device is used and that its length is at most 50 mm.   4. Composite body according to claim 1, characterized in that the length of the composite body is chosen so that the Panel strength at which the Barkhausen jump takes place, in the range between half the saturation field strength of the demagnetizing field up to 2 times the saturation strength of the demagnetizing field. 5. Composite body according to claim 1, characterized in that the composite wire is in tape form. 6. Composite body according to claim 1, characterized in that by the cross-sectional ratio of hard magnetic Jacket and soft magnetic core depending on de remanence the panel strength at which the Barkhausen jump takes place, is a maximum of 5 A / cm. 7. Composite body according to claim 1, characterized in that the cross section of the hard magnetic jacket in Ver bond with its remanence in the magnetized state is chosen so that there is a for the composite body Jump field strength Hs between 1 and 2 A / cm results. 8. Composite body according to claim 1, characterized in that the hard magnetic jacket is lowered by a magnetic field demagnetize right to the longitudinal direction of the composite body is cash.