DE3026482A1 - Theft detection magnetic marker mfr. method - uses transverse bands cut from ribbon of low coercivity magnetic material having attached control strips of ferro-magnetic material - Google Patents

Abstract

The magnetic marker includes a ribbon of magnetic signal material of relatively low coercivity having coupled to it at least two control elements of a ferro-magnetic material. This may be permanently magnetized by a control signal in order to saturate the strip of the ferromagnetic material. This prevents the first ferromagnetic material from generaring higher order harmonics when interrogated by a periodic magnetic signal. The marker used with a system which detects the marker is used with a system which detects the market when it is in an interrogation zone in which a magnetic field varies periodically at a predetermined fundamental frequency. This system includes a sensor for actuating a security readout following the detection of a high harmonic frequency generated by the magnetic marker.

Description

description

The invention relates to a magnetic marking strip to generate a signal within an interrogation zone in which a periodic changing magnetic field with a predetermined fundamental frequency is present, wherein the signal generated by the marking strip is recorded by a scanning device and when a higher order harmonic of the fundamental frequency is detected in it a display is generated, which consists of a signal strip made of ferromagnetic Material with a low coercive force consists on the ferromagnetic material is applied whose coercive force is significantly greater than that of the material of the signal strip.

Different types of anti-theft devices are already known, where marking elements are concealed on or in objects, which consist of a ferromagnetic material, which when excited with a periodically emit a signal with a magnetic signal that changes at a fundamental frequency, contains the higher order harmonic of the fundamental frequency. With some of these systems the marking element contains a control element that is permanently magnetized can to the ferromagnetic signal material of the Marking element saturate magnetically, so that the emission of higher order harmonics Signals is suppressed if the marking element has been deactivated.

In one known anti-theft system (US Pat. No. 3,531,442) the sensor receives a non-linear signal from the ferromagnetic marking element, whose frequency is equal to the difference between the two frequencies of two excitation signals is. A relatively large marking element with permanent magnets is required for this, which is the ferromagnetic base material of the marking element, which is a relatively has low coercive force, activate or deactivate.

It is also already a ferromagnetic marking element in the form a strip of material with low coercive force is known (US Pat. No. 3,820,104), in which a number of circular holes are provided. Over the entire length of the strip is a strip of ferromagnetic material of higher coercive force attached so that there is a number of magnetic pole pairs in the strip when this is introduced into a predetermined magnetic field, whereby the generation of Signals with higher order harmonics is prevented.

The production of this marking strip is relatively expensive, requires a large piece of magnetizable material with high coercive force which also makes the marking strip heavy and stiff. Furthermore, there is a great manufacturing effort, because initially circular holes in the carrier strip made and then it must be ensured that the applied strip is made Material with high coercive force is attached covering the centers of the holes. Another known marking strip (US Pat. No. 3,765,007) consists of a ferromagnetic one Tape or strip, the ferromagnetic elements or areas with different Has coercive force, so that the magnetization of the various elements or reverses areas in a periodically changing magnetic field one after the other, i.e. there are elements or areas with different magnetic properties provided, in order to increase the magnetic field, the elements or areas one after the other to bring it into another magnetic state and thereby an identification signal to radiate. Such a marking strip is relatively expensive in the Manufacture, which is a particular disadvantage in a mass product.

It is the object of the invention to provide a simply structured marking strip to create that can be mass-produced at low cost.

To solve this problem, a marking strip of the type mentioned at the outset is used Art designed according to the invention such that the signal strip opposite his Width is formed relatively long and in a first, non-magnetized State due to the magnetic field in the interrogation area. Signals containing harmonics radiates and in a second state in this magnetic field containing no harmonics Signal emits, and that the ferromagnetic one having the greater coercive force Material in the form of several control elements at a distance from one another on the signal strip is arranged, the width of the control elements substantially equal to the Width of the signal strip is and wherein the control elements in a first, non-magnetized State the signal strip in the first state and in a second, magnetized State switch the signal strip to the second state.

Further refinements of the invention emerge from the subclaims.

The invention is explained in more detail below with reference to the figures.

Fig. 1 shows the web material wound on a roll for the Production of the magnetic marking strips according to the invention and their application several strips of ferromagnetic control material on the web material.

Fig. 2 shows a top view of a magnetic according to the invention Marking strips.

FIG. 3 shows the marking strip from FIG.

Fig. 4 shows one of U.S. Patent 3,820,103 and U.S. Patent 3,820,104 known magnetic marking strips.

In Fig. 2, a magnetic marker strip 10 is shown, which from a signal strip made of ferromagnetic material with a relatively low Coercive force of about 0.1 oersted to about 0.01 oersted. The signal strip 11 consists of an elongated, substantially rectangular piece, the one forms an open strip, i.e. a strip with separate poles when magnetized has, and is not endless or wound with overlapping areas became. The material of the strip is chosen so that its ferromagnetic Particles change their polarity with every sinusoidal change in a magnetic interrogation field change. The signal strip 11 is usually in this way in the interrogation area introduced that its main dimension or its longitudinal axis 12 is parallel to itself sinusoidally changing magnetic field is directed. Usually the magnetic field a peak amplitude of about 1 Gaussian and a frequency between 60 Hz and 10 kHz.

The material used for the signal strip 11 is usually a conductive, The ferromagnetic alloy of nickel, molybdenum, manganese and iron used is referred to as Mopermalloy or simply Permalloy.

The material of the strip 11 is annealed so that a maximum Sensitivity at the final coercive force (H) gives that between 0.01 Oersted and c 0.1 oersted, with a coercive force of less than 0.05 Oersted is preferred and where the ratio of BR / RS is 0.6 to 0.8 and typically Is 0.7. Although not essential to the invention, it should be noted that the used Signal strip material has a relatively large permeability of about 200,000 Gauss / Oersted has.

The signal strip 11 preferably has a thickness of 0.018 mm and a width of 3.18 mm. These dimensions however, are not critical and can easily be changed up to -20% without any change in operation results in a noticeably changed effect. The length of the signal strip is 11 in The direction of its longitudinal axis 12 is generally about 7.6 cm, but can be in Depending on the intended use and the object to be marked standing room be less than 5 cm or up to 18 cm.

The signal strip 11 has a first or unmagnetized state, in which it emits a signal containing harmonics when it is connected to a periodic, magnetic signal of the fundamental frequency, about the interrogation signal is excited. Even though any signals with higher order harmonics can be received in order to to indicate the presence of the signal stripe in the first state are customary the 18th to the 20th

Harmonics or harmonics of the fundamental frequency of the interrogation signal determined. In a second or magnetized state, the signal strip 11 does not emit any radiation Signals containing harmonics from when excited, or at least only one Signal that differs in its harmonic content from that typically in the first The state of the emitted signal differs significantly.

The signal strip shown in FIG. 2 also has several control elements 21, 22, 23 and 24, which in the following description for Simplification and also denoted by 20 because of their identical shape and properties will. The control elements are at a distance from one another and in the direction of the longitudinal axis 12 distributed on the signal strip attached. They consist of a ferromagnetic Material with a coercive force that is at least 500 times, preferably that 1000 times the relatively low coercive force of the signal strip 11 is. The minimum coercive force should be at least 100 oersted and preferably 150 to 250 oersted. The control elements 20 should have a remanence (B) of at least 5000 Gauss, preferably from 8000 Gauss to 12,000 Gauss.

They are usually made from an alloy of cobalt, vanadium and iron known as Vicalloy.

The width of the control elements 20, i.e. their dimension perpendicular to the longitudinal axis 12 of the signal strip 11 is generally equal to the width of the Signal strip 11. Typical dimensions of the control elements 20 are a width of 3.18 mm, a length of 3.81 mm and a thickness of 0.05 mm. Have investigations shown that below a minimum size of the control elements 20 is not a satisfactory one Function in connection with the signal strip 11 is achieved. This minimal dimension is usually 3.81 x 3.18 x 0.05 cm.

Larger control elements 20 work with the same effectiveness, lead however, both an increase in material costs and disadvantages as a result the resulting larger dimensions of the marking strips 10 formed.

If the control elements 20 are not magnetized, the signal strip radiates 11 in an interrogating magnetic field of the fundamental frequency with higher harmonics, wherein the control elements 20 usually do not interfere with this process. The main task of the control elements 20 is the signal strip 11 in its second or magnetized state, due to the absence of higher harmonics in the emitted signal or at least through a significant change in the emitted signal Signals is marked to lock magnetically. When the controls 20 are permanently magnetized, they form magnetic poles, which are generally adjacent to the edges of the control elements that limit the width dimension 20 and the signal strip 11 are located. The one between the magnetic poles of the control elements 20 running magnetic field lines hold the ferromagnetic material in the adjacent sections of the signal strip 11 in the corresponding alignment, i.e. usually perpendicular to the longitudinal axis 12, even if a there is a strong interrogation signal. The remanence of the control elements 20 prevents a reversal of the ferromagnetic elements in the signal strip 11 due to the magnetic Interrogation signal. Therefore, the remanence of the control elements 20 must be to a certain extent Distance from them still produce a sufficiently large effect so that the ferromagnetic Elements of the signal strip 11 are effectively magnetized or saturated.

It should be noted that the magnetic interrogation signal -not is so large that it causes the permanent magnetization of the control elements. Rather, the interrogation signal is much weaker, but strong enough to the signals of the higher harmonics emitted by the signal strip 11 when interrogated to excite. In contrast, the control elements 20 are relatively by applying a large magnetic constant field magnetized in the area of the marking strip.

This constant magnetic field is typically of an order of magnitude from 250 oersted. This strong magnetic field brings the control elements 20 into one permanent magnetic state, whereby the signal strip 11 is desensitized. Other common methods of magnetizing and demagnetizing the control elements 20, such as the methods of US Pat. No. 3,765,007, can also be used.

The control elements 20 are on the signal strip at a distance arranged from each other by the remanence of the material used for them is determined. In one embodiment, this distance was about 3.18 mm, see above that then the ferromagnetic elements in the sections of the signal strip 11 came between the control elements 20 in a magnetically saturated state.

As shown in Fig. 1, the magnetic marker strips 10 in a simple and inexpensive way to produce that one on a web Signal strip material applies strips of material to form the control elements, and then cut the web material in the transverse direction, in this way the magnetic To obtain marking strips 10. For this purpose, the rolled up web material 11 is from withdrawn from the roller held by a shaft 41. The material strips 51, 52, 53, 54, which consist of the ferromagnetic material for the control elements, are on a common axis 56 and thus form a unit 50. The The distance between the rolled up strips of material 51, 52, 53, 54 must be maintained so that the material strips at the desired distance on the upper surface of the Web material 11 can be applied. The material strips of the control elements will then onto the web material by means of two pressure rollers 61 and 62 pressed on and connected to this. The pressure rollers 61 and 62 pull the strips of material and the web material from, and on their other side that occurs with the material strips provided web material. Depending on the materials used as strips of material and are used as web material, a non-magnetic one can be used to connect them Glue can be used. Furthermore, on the underside of the web material 11, paper or another non-magnetic carrier material can be attached with which Help the marking strips attached to the objects to be marked by gluing can be.

After joining the two materials, the sheet material becomes one schematically illustrated cutting device 70, 71 (Fig. 1) supplied, which the Material web perpendicular to its longitudinal axis, which is perpendicular to the longitudinal axis 12 of the Marking strip 10 runs, cut up.

After the first cutting process, the rollers 61 and 62 can step by step are moved to the cutting device the desired lengths of web material 11 to be fed so that a marking strip 10 is then cut off in each case. It it is readily apparent that the production of a large number of essentially smoothly formed magnetic marking strips take place it is possible to use materials wound on rolls to then unwind the material strips of the control elements with the web material of the signal strips connect to.

Claims (13)

Magnetic marker strip A r, s p rü c h e 1. Magnetic marker strip to generate a signal within an interrogation zone in which a periodic changing magnetic field with a predetermined fundamental frequency is present, wherein the signal generated by the marking strip is recorded by a scanning device and when a higher order harmonic of the fundamental frequency is found in it a display is generated, which consists of a signal strip made of ferromagnetic Material with a low coercive force insists on the ferromagnetic material is applied whose coercive force is significantly greater than that of the material of the signal strip, characterized in that that the signal strip (11) is relatively long compared to its width and in a first, unmagnetized state as a result of the magnetic field in the harmonics interrogation area emits containing signals and in a second state in this magnetic field does not emit a signal containing harmonics, and that this has the greater coercive force expelling ferromagnetic material in the form of several control elements (21, 22, 23, 24) is arranged at a distance from one another on the signal strip (11), wherein the width of the control elements (21, 22, 23, 24) is essentially equal to the width of the signal strip (11) and wherein the control elements (21, 22, 23, 24) in a first, unmagnetized state, the signal strip (11) in the first state and in a second, magnetized state, the signal strip (11) in the second Switch state. 2. Marking strip according to claim 1, characterized in that the Coercive force of the signal strip (11) in the range from 0.01 oersted to 0.1 oersted and the coercive force of the control elements (21, 22, 23, 24) in the range of 100 Oersted to 2,500 Oersted. 3. Marking strip according to claim 1 or 2, characterized in that that the coercive force of the control elements (21, 22, 23, 24) is at least 500 times is the coercive force of the signal strip (11). 4. Marking strip according to one of claims 1 to 3, characterized in that that the width delimiting edges of the control elements (21, 22, 23, 24) with align the width delimiting edges of the signal strip (11). 5. Marking strip according to one of claims 1 to 4, characterized in that that the magnetic poles of each control element (21, 22, 23, 24) in the second, magnetized State adjacent to the width-limiting edges of the signal strip (11) are located. 6. Marking strip according to one of claims 1 to 5, characterized in that that the length of the control elements (21, 22, 23, 24) is less than their width. 7. A method for producing a marking strip according to one of the Claims 1 to 6, characterized in that a magnetizable web material with low coercive force axially parallel to its longitudinal axis at least two proportionally narrow strips of a magnetizable material with a significantly higher coercive force are applied and connected to the web material and that the web material and the strips connected to it to form the marking strips transversely to the longitudinal axis of the web material are cut. 8. The method according to claim 7, characterized in that the web material for applying the strips as well as for the subsequent cutting step-by-step accordingly the desired width of the marking strips to be produced in the direction of its longitudinal axis is moved. 9. The method according to claim 7 or 8, characterized in that the Strips when applied to the web material at a predetermined distance from one another being held. 10. The method according to claim 9, characterized in that the strips be kept at a distance from each other at least equal to the width of a Strip is. 11. The method according to any one of claims 7 to 10, characterized in that that the web material and the strips perpendicular to the longitudinal axis of the web material be cut up. 12. The method according to any one of claims 7 to 11, characterized in that that the web material and the strips are connected to one another by gluing. 13. The method according to any one of claims 7 to 12, characterized in that that the strips are magnetized after cutting the web material in such a way that that the magnetic poles of each control element formed by a respective strip section lie on an axis parallel to the longitudinal axis of the web material.