DE69837528T2 - MAGNETIC LABEL - Google Patents

Description

TECHNICAL BACKGROUND THE INVENTION

Technical field of the invention

The The invention relates to a magnetic label used in an electronic Device for monitoring of Articles should be used.

Technical background the invention

Around To prevent the theft of articles have been many lately used electronic article surveillance devices Service. A special label is attached to a target article and such a monitor detects on a signal generated by the label, the presence of the Article. There are some system types that are mainly used in a system a magnetization process of a special soft magnetic Materials, a system for using a sudden change in impedance an LC resonant circuit at a given frequency and a System for emitting a special electric wave from one Be divided into a resonant circuit.

From In the above systems, the magnetic system has recently been widely used been used because a label can be delivered inexpensively. The magnetic system roughly becomes a magnetostrictive type Uses vibrations, and a type with application of hysteresis behavior divided.

details Magnetic label and system with application of hysteresis behavior are described in, for example, Japanese Patent Publication No. 3-27958 (1991). disclosed. According to this publication is used as a magnetic label, a material that has a having an Fe-based amorphous metal wire. A detection system is installed in an area where articles are monitored and by an exciter coil For example, a magnetic alternating field of 73 Hz as an interrogation signal generated. As a result, when the magnetization of the magnetic field in the magnetic Label metal wire is reversed, in the detection coil induced a voltage and detected as a detection signal. The above mentioned Material of the metal wire is characterized in that its Magnetization in the longitudinal direction is very stable, and the magnetization becomes accurate at the same time then vice versa, when the magnetic field reaches a critical value, and the river reversal will be completed immediately. This property is bistable and is often considered great Barkhausen jump called. Therefore, in the arousal of a such material by a large amplitude a discontinuous and very sudden Magnetization step observed in a hysteresis loop and can be recognized. In case of sudden Magnetic reversal in the label becomes a very high in the detection coil high pulse voltage induced. Because the waveform of the induced Voltage compared to other general magnetic materials, such as B. one for used a shopping basket iron sheet, is very unusual it can be easily distinguished. In the above system will performed a frequency analysis of the induced voltage waveform, and according to the amplitudes and the time course of the generation higher Harmonious is decided whether the label is present or not, and besides it is decided if the triggering a warning is necessary or not.

Another magnetic tag and system utilizing hysteresis performance is disclosed in Japanese Patent Publication No. 3-55878 (1991) (1991). EP 0 153 286 A2 ) disclosed. In this system, a magnetic label having an amorphous Co-based metal tape and the like is used. These materials are known as so-called high permeability materials, and since their magnetostriction and magnetocrystalline anisotropy are small and their coercive force is low, they are very easily magnetized. When these materials are magnetized by a high amplitude magnetic field, a very narrow and continuously changing hysteresis loop is observed. If a piece of these materials contained in the magnetic label is long enough, the magnetization increase of the hysteresis loop becomes steep. This means that a magnetic flux change in the monitoring system occurs suddenly. Similar to Japanese Patent Publication No. 3-27958 (1991), in this system, an alternating magnetic field is generated in a monitoring area by an exciting coil, and a voltage induced in a detection coil is detected as a signal. The alternating magnetic field used in this system has a combination of several frequencies, for example 25 Hz, 1.5 kHz and 2.5 kHz. When the high-permeability material contained in the magnetic label is magnetized, a pulse voltage containing a frequency component of the sum of or the difference between 1.5 kHz and 2.5 kHz is generated in the detection coil. Therefore, if the magnitude of a voltage signal having a frequency of 4 kHz obtained by adding 1.5 and 2.5 kHz is not smaller than a predetermined value, for example from that concluded that the magnetic label is present. Furthermore, a low-frequency magnetic field of 25 Hz is superimposed in this system. Since this magnetic field saturates the label at 25 Hz, the above mixed frequency signal of the sum or difference is generated only at a zero crossing point in the 25 Hz magnetic field. Therefore, the sensitivity of the system can be ensured by controlling the generation of the mixed frequency signal and a phase of the magnetic field of 25 Hz.

In The above magnetic electronic article surveillance system is magnetic Etiquette exclusively for corresponding Types have been used. That is, in a system that is through in Japanese Patent Publication No. 3-27958 (1991) became amorphous Used Fe-based metal wire showing the big Barkhausen jump, and a thin one Co-based amorphous metal tape, which is a highly permeable material is was used in a system as in Japanese Patent publication No. 3-55878 (1991).

The Use of the exclusive etiquette in the respective systems, however, narrows the scope of application of the systems. Lately is required been that etiquette for monitoring of articles are adhered to products in their manufacturing phase. This is called factory gluing or labeling at the source designated. Because products are sold that are already etiquette for monitoring have the etiquette not glued to products in shops to become, and therefore can the administrative costs are lowered. However, as mentioned above, there it in several types of magnetic systems corresponding magnetic Etiquette, and the etiquette of other types can not each other through the Systems are detected. This will increase the spread of the factory Attaching magnetic labels prevented.

If therefore the magnetic etiquette in different electronic Article surveillance systems be used by the magnetic type, their sensitivities need be good enough in the respective system. That way that can factory attachment for the magnetic system in large Scope to be developed. It is desirable that a magnetic High sensitivity label especially in a system from the so-called big one Barkhausen type as disclosed in Japanese Patent Publication No. 3-27958 (1991) discloses as well as in a system of the so-called high type Permeability used can be as disclosed in Japanese Patent Publication No. 3-55878 (1991) disclosed.

A Object of the present invention is a magnetic To provide label of small dimensions, with high sensitivity both in a system of the so-called big Barkhausen type as well used in a system of the so-called high permeability type can be.

Disclosure of the invention

The Inventors state that this above problem can be solved by using a magnetic label can, which consists of a soft magnetic material whose magnetic Characteristic curve carefully is limited to get to the present invention.

A magnetic label according to the invention comprises a soft magnetic material which can produce a sudden Ummagneti tion and whose length is not greater than 70 mm. When an external magnetic field having an amplitude of not more than 0.2 Oe is applied, the soft magnetic material generates a sudden remagnetization with a magnetic flux change of not less than 8.0 × 10 ^-9 Wb.

Preferably The soft magnetic material generates the sudden remagnetization when the magnetic field amplitude by an amount less than or equal to 0.1 Oe is staggering.

Preferably, in the magnetic label, an amount of the magnetic flux radiated around the soft magnetic material as a concomitant of the sudden remagnetization is not smaller than 8.0 × 10 ^-9 Wb.

Preferably has the soft magnetic material in the magnetic label a difference between signal amplitudes at 1.5 Hz and 3.5 Hz less than -3 dBm on when the sinusoidal Magnetic field with an amplitude of 1.5 Oe at a frequency of 73 Hz is applied.

In the magnetic label is the soft magnetic material, for example a wire.

In the magnetic label is the soft magnetic material, for example a band.

In the magnetic label is the soft magnetic material, for example a thin film.

In The magnetic label, for example, two types of soft magnetic Materials arranged close together.

In the magnetic label is, for example, the soft magnetic Wire or thin film material on the soft magnetic thin film material arranged.

In The magnetic label is, for example, a hard magnetic Material with a higher Coercive force than that of the soft magnetic material near the soft magnetic material arranged.

The invention will be explained in more detail here. The magnetic tag according to the present invention is a small-sized magnetic tag whose length is not larger than 70 mm. The magnetic label contains the soft magnetic material, and the soft magnetic material has the property that the sudden remagnetization occurs upon application of an external alternating magnetic field whose magnetic field amplitude exceeds a certain critical value. Preferably, the magnetic field amplitude at which the soft magnetic material is re-magnetized is not higher than 0.2 Oe, and the fluctuation of the critical magnetic field is not higher than 0.1 Oe, and a change of the magnetic flux radiated outward in the sudden remagnetization is not less than 8.0 × 10 ^-9 Wb. The magnetic tag according to the present invention, which is made of the soft magnetic material having a carefully limited magnetic characteristic, can be used both in the so-called Barkhausen type system represented by that disclosed in Japanese Patent Publication No. 3 No. 27958 (1991) as well as being used with high sensitivity in the so-called high permeability type system represented by the system disclosed in Japanese Patent Publication No. 3-55878 (1991).

There the inventive magnetic Label containing soft magnetic material by applying a weak magnetic field a sudden Can have magnetic reversal, can be the magnetic label suitably in a variety of electronic anti-theft systems use, such. In a system that has an element with the big Barkhausen effect and in a system using a high permeability element.

Short description of drawings

These and other objects and features of the present invention from the following description in conjunction with its preferred embodiments with reference to the attached Drawings become clear. Showing:

1A to 1F schematic plan views of various magnetic sensors;

2 a perspective view of a monitoring door space; and

3 a perspective view of three types of spatial positions of a magnetic sensor.

Best styles the invention

below become embodiments of the invention with reference to the drawings attached hereto explained.

First, will the limitation of a magnetic characteristic of a soft magnetic material described as part of a magnetic label. An inventive magnetic Label is small, d. H. his length is not bigger than 70 mm, so that it Can be used when attaching the factory. The length is preferably not larger than 50 mm, stronger preferably not larger than 25 mm. Its lower limit is not subject to any particular restriction; there but the strength of a demagnetizing field of a magnetic material increases it actually not preferable that the Length not greater than 10 mm.

The magnetic label according to the invention contains the soft magnetic material, which can be reversed magnetically when the amplitude of an alternating magnetic field exceeds a critical value. The sudden remagnetization means that the magnetization direction of the soft magnetic material changes within a very short time or with a very small change in the magnetic field. If the magnetic hysteresis curve is observed in such a magnetic material, one recognizes one step-like change range. Such a step-like remagnetization has the feature that it is influenced by the largest amplitude of the magnetic field applied to the material. For example, materials referred to as large Barkhausen jump materials generally cause a sudden remagnetization at a given critical magnetic field, and the hysteresis curve has a step-like change. However, the magnetization is not reversed at a magnetic field smaller than the critical magnetic field, and no hysteresis is observed. In another example, a material exhibits remagnetization at a relatively small magnetic field, but the change is smooth and the hysteresis curve is steady. However, if a magnetic field is greater than or equal to the critical value, a sudden remagnetization occurs and the hysteresis curve has a step change. A material in which both cases occur can be used as the magnetic tag of the present invention since a sudden remagnetization occurs at a magnetic field greater than or equal to the critical value.

The suddenness can z. B. judged by a frequency analysis of the magnetic pulses which, as a concomitant of the sudden re-magnetization in the surroundings are radiated. When the magnetization of a magnetic Material is reversed, then secondarily the magnetic field in the environment radiated. When the remagnetization occurs suddenly, it changes the radiated magnetic field instantly. If a coil in the Near the is brought to magnetic material, then enters the coil induced electrical voltage pulse. The frequency analysis of the electric voltage pulse signal is performed, and the signal amplitude at different frequencies and their ratios are compared to the suddenness to assess the remagnetization. That is, the remagnetization is as a sudden judged when the amplitude is stronger at the higher frequency. The amplitude is assessed in a generalized way by: she using a relationship from signal amplitudes at different frequencies to amplitude at the same frequency as that of the magnetic field to be applied normalized, the influence of the technical data of the measuring instrument, the Size of the magnetic Materials and the like can be reduced. A method that a relationship uses signal amplitudes at two frequencies that are sufficient are higher as the stimulating fundamental frequency, is a simple assessment method. If z. B. a sinusoidal Magnetic field with the amplitude of 1.5 Oe at a frequency of 73 Hz is applied to a magnetic material, the suddenness the remagnetization by means of a difference between signal amplitudes at 1.5 kHz and at 3.5 kHz. If z. For example, the difference is smaller as -3 dBm, it is decided that a very sudden Magnetic reversal occurs and the material is suitable for the invention. With decreasing difference, the magnetic material is more suitable and it is stronger to be preferred if the difference is less than or equal to -2 dBm.

The magnetic tag according to the invention contains a soft magnetic material in which a sudden remagnetization is observed when an external alternating field is applied to the magnetic tag whose magnetic field amplitude exceeds a certain critical value. The magnetic label has a sufficiently high sensitivity in a so-called Barkhausen type system and in a so-called high permeability type system. When an alternating field of 73 Hz is applied to the soft magnetic material, the magnetization of the soft magnetic material is suddenly reversed by a magnetic field intensity of not more than 0.2 Oe, and its magnetic field strength is preferably not larger than 0.15 Oe, and more preferable not larger than 0.1 Oe. Their lower limit is not particularly limited, and as the value decreases, the sensitivity increases, but when the value decreases to less than about 0.03 Oe, sensitivity rarely changes. Meanwhile, in a soft magnetic material whose magnetic field is high, that is, exceeds 0.2 Oe, the sensitivity is lowered particularly in the so-called high permeability type system, so that this material is not preferable for the present invention. If the magnetic label is excited by a sufficiently strong magnetic field, then this magnetic field strength has the physical meaning that it corresponds to a coercive force of the soft magnetic material. The coercive force generally tends to depend on the amplitude of a field of excitation, and the above-mentioned value approximately corresponds to the coercive force upon excitation of the magnetic label by the amplitude of 1 Oe. In order to obtain a magnetic label with high detection sensitivity in the systems, it is preferable that the dependence of the coercive force on the exciting field strength is small. For example, a difference in coercive force when the label is excited by 1 Oe and 5 Oe is within 50% of the coercive force when the magnetic label is excited by 5 Oe. In addition, it is well known that the coercive force depends on the exciting frequency, and it is preferable that the difference between the coercive forces when the tag is excited, for example, 73 Hz and 1 kHz is within 50% of the coercive force when excited by 1 kHz. Here, a critical magnetic field necessary for the remagnetization exists in the soft-magnetic material to be used for the magnetic label according to the invention, and a discontinuous remagnetization behavior occurs around the critical magnetic field. For example, in a state in which a magnetic field is applied which is weaker than the critical magnetic field, the Mag Magnetization of the soft magnetic material is not reversed at all, but just when the value reaches the critical magnetic field, the magnetization is suddenly reversed. In the present invention, the critical magnetic field amplitude is preferably not larger than 0.15 Oe, and more preferably not larger than 0.1 Oe.

Next, the inventors state that even if the magnetic field reversal is within the range of the above conditions, the detection sensitivity in the systems is insufficient if a magnetic flux change due to the remagnetization does not exceed a certain range. That is, a change in magnetic flux radiated by the soft magnetic material contained in the label due to the sudden remagnetization should not be smaller than 8.0 × 10 ^-9 Wb. The magnetic flux change is preferably not smaller than 9.0 × 10 ^-9 Wb, and more preferably not smaller than 10.0 × 10 ^-9 Wb. The magnetic flux change is measured in the following manner. An AC MH loop is measured with an alternating magnetic field of a frequency corresponding to the system (e.g., 73 Hz in a system disclosed in Japanese Patent Publication No. 3-27958 (1991)) and a magnetization change observed in the hysteresis loop in the case of sudden remagnetization, the magnetic flux change is considered. If the magnetic flux change is smaller than 8.0 × 10 ^-9 Wb, the intensity of a signal generated by the magnetic tag is weak, and this situation is not desirable, because the detection sensitivity is high in the so-called Barkhausen type system ^{disclosed in} U.S. Patent No. 5,436,074 Japanese Patent Publication No. 3-27958 (1991).

When next will be a temporal change the magnetic field in a magnetic reversal studied in detail. As a result you realize that especially Japanese Patent Publication No. 3-27958 (1991) revealed the so-called large Barkhausen-type system's fluctuation of the magnetic field causing remagnetization, the detection sensitivity of the label strongly influenced, and that one excellent sensitivity can not be achieved if that Magnetic field is not within a certain range. The is called, it is desirable that at a remagnetization of soft magnetic contained in the label according to the invention Materials the magnetic field strength within a range of 0.1 Oe. The fluctuation range is preferably not larger than 0.07 Oe and stronger preferably not larger than 0.05 Oe. The change of Ummagnetisierungsfelds means in this case that when repeated Apply an alternating field with uniform amplitude to the same magnetic label the magnetic field strength for the remagnetization of the soft magnetic material in the magnetic label is in changes every cycle. Their value is in the following manner in the present invention assessed. The Ummagnetisierungsfeldstärke is continuously in Measured 20 cycles, and an average of the Ummagnetisierungsfeldstärke in positive and negative cycles are calculated. Next are absolute values of differences between the average Ummagnetisierungsfeldstärke in positive and negative cycles and actual magnetic field strength calculated, and a sum of the results is divided by 40. The obtained Value is defined as the fluctuation of the magnetic field. If the fluctuation of the magnetic field exceeds 0.1 Oe, is disclosed in Japanese Patent Publication No. 3-27958 (1991) disclosed the so-called large Barkhausen type system detection sensitivity extremely diminished, and therefore it is not preferable.

The magnetic tag of the present invention, which is made of the soft magnetic material having the above magnetic characteristic, can be realized by various structures, and therefore is not particularly limited in the present invention. Concrete examples of the soft magnetic material suitable for the magnetic tag of the present invention are as follows. For example, an amorphous metal wire is produced by a melt spinning method in a rotating liquid disclosed in Japanese Patent Publication No. 56-165016 (1981), or an amorphous metal tape is disclosed by a disclosed in Japanese Patent Publication No. 3-27958 (1991) Single roll device, and the wire or ribbon is suitably used as the soft magnetic material of the magnetic tag of the present invention. When subjected to heat treatment under tension, torsion, magnetic field, electric current flow or the like, the magnetic field of the remagnetization and its magnetic flux change can be arbitrarily set. When the wire or strip is subjected to a wire drawing process, rolling process, slitting process or the like before the heat treatment, it can be made into a desired shape, and thus, such processes are effective because a demagnetizing field can be regulated. Besides the wire and the ribbon, a thin film of magnetic material may be suitably used as the soft magnetic material according to the present invention. Such a magnetic thin film material is z. In Japanese Patent Laid-Open Publication No. 4-218905 (1992). According to this document, a soft magnetic thin film can be provided which has a sudden remagnetization behavior at a critical value and is therefore useful in the task of underlying invention is suitable.

The 1A to 1F show schematically different magnetic labels. 1A shows a magnetic label containing a soft magnetic wire 12 which is adhered to a polyethylene terephthalate (PET) film 10 is glued on, 1B shows a magnetic label with a thin soft magnetic band 14 attached to a PET film 10 is glued on, and 1C shows a magnetic label with a soft magnetic thin film 18 attached to a PET film 10 is glued on.

Further, the magnetic tag of the present invention can be constructed by combining two kinds of magnetic materials, and it is expected to improve performance. For example, as in 1D shown, two pieces of soft magnetic material 16 at two ends of a linear soft magnetic material 12 arranged in contact with each other. Then, the label has a higher sensitivity for an anti-theft system than a label having only the one long magnetic material, and a more compact magnetic label can be provided. It is assumed that the two pieces of soft magnetic material 16 how a magnetic yoke works that concentrates the adjacent magnetic field to direct it to the linear magnetic material. A similar benefit is also observed when using a linear magnetic material 12 with a magnetic thin film 18 on a PET film 10 combined, as in 1E shown. In this case, it is preferable that the linear magnetic material is applied to a magnetic thin film layer. In particular, the advantage is remarkable when the magnetic thin film has magnetic anisotropy with the longitudinal direction of the linear magnetic material being in the direction of the magnetically hard axis of the thin film, and good performance can be obtained on the label.

The Length of the The above soft magnetic material is not subject to any particular Restriction. Since the above magnetic material can not become longer than the magnetic one Label, however, is desirable that his Length at least not bigger than 70 mm, and preferably 10 to 70 mm, more preferably 20 to 60 mm is.

There a demagnetizing field affecting the soft magnetic material is a relationship between its cross section and its length is important. In the case of a wire material, for. B. material with a diameter of 30 μm and a length of 10 mm can be used in a suitable manner. On the other hand exists with a diameter of 100 μm, if the length is not bigger, the tendency to deteriorate the characteristics of the material. In this case, the length is for example, preferably greater than or equal to 20 mm. A ribbon and a thin layer have the same tendency in this case. There is the Tendency that the intensity a signal generated by the magnetic label strongly from the volume, especially is dependent on the cross section of the soft magnetic material. This means, it is desirable that the Size of the soft magnetic Materials under consideration the required signal intensity is set.

The deactivating function can be added to the magnetic label of the present invention by using, in addition to the above soft magnetic material, another magnetic material having other properties. That is, as in 1F is shown, in the vicinity of the soft magnetic material (in this example, in three places) a hard magnetic material 20 arranged, whose coercive force is stronger than that of the soft magnetic material 12 , By remanent magnetization of the hard magnetic material, a bias field can be applied to the soft magnetic material. The deactivating function may be provided by the magnetic label having such a structure. When the hard magnetic material is neutralized in the label, the soft magnetic material has the inherent sudden magnetic reversal and the label reacts in a monitoring area. However, when the hard magnetic material is magnetized, the remagnetization of the soft magnetic material is prevented. Therefore, the label does not respond or is disabled. Since the label can be deactivated or activated by a simple device, a user can generally use the electronic article surveillance system for various applications. As a hard magnetic material to be used for such a task, a metal strip is suitably used, as z. B. from Arnochrome (Arnold) or Semivac (vacuum melt) can be obtained. Further, a paint containing magnetic powder, a hard magnetic film such. As Ni and the like can be used.

The magnetic tag of the present invention is usually used in the form of a sticker, a tag and the like having an adhesive layer, but the present invention is not limited to these forms. For the understanding of the invention, a magnetic label in the form of a sticker will be described as an example. In the label is the soft magnetic material that is in the surveillance area generates a signal between two paper or plastic foil layers. On an inner surface of the paper or the film, an adhesive layer is applied, so that the soft magnetic material is held thereon. In addition, if the hard magnetic material for the deactivation function is included, it is arranged so that it is in close contact with the soft magnetic material and is disposed between the two paper or Kunststofffolielagen. An additional adhesive layer is applied to an outer surface of one of the two paper or plastic film layers, and the label is adhered by this adhesive layer to an article whose monitoring is required. Such labels are continuously adhered to a paper roll, and the paper is wound up and delivered to a user. The label is then removed from the paper for use by a hand labeller, an automatic gluer, or by hand. Here, an imprint or the like is applied to an outer surface of the other paper or film layer where no adhesive layer is formed according to a task.

below An example of the magnetic tag will be described.

Production of soft magnetic material

First, the preparation of samples in Examples 1 to 3 and Comparative Examples 1 and 2 will be described. Metal wires with properties shown in Table 1 are prepared by a melt spinning method in a rotating fluid. The production conditions are the following. A stock alloy of about 200 g is placed in a quartz nozzle and melted by high-frequency induction in an argon atmosphere. The argon gas pressure is increased to about 4.5 kg / cm ² , and liquid metal is ejected from a nozzle bore having a diameter of about 130 μm. The liquid metal is ejected onto a cooling water layer formed on an inner wall of a cylinder drum having a diameter of 600 mm, which rotates at about 300 rpm, and is rapidly cooled to solidify. Then the metal is wrapped around the inner wall of the drum. The wire thus obtained is subjected to a wire drawing process with a drawing die to obtain a given wire diameter. Then it is subjected to a heat treatment at 340 ° C under a tensile stress of 135 kg / mm ² for 10 minutes. The metal wire obtained in this way is cut to a length of 65 mm and is inserted between two PET film layers with a thickness of 25 microns, to which an adhesive of 23 microns thickness has been applied for fixing. The obtained magnetic label is Example 6. In Examples 1 to 3, wires subjected to the above-mentioned heat treatment under tension are further subjected to heat treatment at 400 ° C. for 10 minutes without tension, and the wires obtained above are made similar Processed to produce magnetic label according to Examples 1 to 3. Here, Comparative Example 1 is subjected to the wire drawing process, so that it becomes 50% thinner than Examples 1 and 2.

• * Außerhalb des Umfangs von Anspruch 1.

In the following, the preparation of Examples 4 and 5 and Comparative Example 2 will be described. Metal strips have properties shown in Table 1 and are made using a single roll device. The manufacturing conditions in the single-roll process are as follows. A stock alloy of about 200 g is introduced into the quartz nozzle and melted by high-frequency induction in an argon atmosphere. The argon gas pressure is increased to about 2 kg / cm ² , and liquid metal is ejected from the nozzle bore having a diameter of about 300 μm. The liquid metal is ejected onto an outer peripheral surface of a copper roll having a diameter of 200 mm, which rotates at about 1200 rpm to rapidly cool and solidify, and is wound onto a roll by a take-up device. The metal strips obtained in this way are twisted 10 or 5 times per 1 m and simultaneously subjected to a heat treatment at 320 ° C for 10 minutes. Then, they are processed for the production of magnetic labels by the same method as in Example 1. The obtained samples are Examples 4 and 5. In Comparative Example 2, a belt obtained by the single-roller device is not subjected to heat treatment and is used as Comparative Example 2 of the magnetic label. Table 1. Properties of different samples

• * Outside the scope of claim 1.

Measurements of the crystal structure and shape of samples:

structures The above samples are analyzed by X-ray diffraction and only one halo structure is observed on all samples. Then the structures are identified as amorphous phase. to Shape of the samples will be as well Cross sections in 10 points of the samples through an optical OPTIPHOT microscope of Nikon observes, and an average of the cross sections is measured. A magnetic hysteresis characteristic is provided by an ac hysteresis meter ACBH-100K from Riken Electron Co., Ltd. measured. A probe coil of 100 Windings with a compensation coil whose diameter is 30 mm and their length 20 mm, is in a 60 mm diameter exciter solenoid, a length arranged by 198 mm and 189 turns. Every sample of the examples 1 to 5 and Comparative Examples 1 to 3 is so in the probe coil used that the Position of the probe coil coincides with the center of the sample. By a field magnet coil becomes a magnetic alternating field of 73 Hz generates, and a change the magnetization of the samples is detected by the probe coil. The hysteresis loop obtained in this way is used to check whether the magnetization of the respective samples discontinuously and suddenly changes or Not. Further, a magnetic field strength and a magnetic flux change measured during the remagnetization. To the suddenness of the magnetic reversal To investigate, a frequency analysis is made by a sample performed magnetic signals. A function generator 3341A from Hewlett Packard and a fast-response power amplifier from NF Electronics Instrument will be equipped with a Helmholtz coil of 400 mm diameter connected to a sinusoidal magnetic field in the center position with a frequency of 73 Hz and an amplitude of 1.5 Oe to produce. A detection coil of 200 turns is in the middle positions and a sample is placed in the detection coil. An output signal of the detection coil is subjected to a frequency analysis with a Hewlett Packard 35665A Dynamic Signal Analyzer subjected. The signal amplitude at each frequency is in dBm represented on a 1 mV basis. In particular, a difference the harmonic signal amplitudes at 1.5 and 3.5 kHz as an indicator for the suddenness the remagnetization judged.

Measurement of sensitivity of the label

A Sensormatic system is selected as the large Barkhausen type system disclosed in Japanese Patent Publication No. 3-27958 (1991), and a Esselte Meto 2200SA system is described as that disclosed in Japanese Patent Publication No. 3-55878 (1991). The high permeability system disclosed is selected, and the detection sensitivity of the magnetic labels according to Examples 1 to 5 and Comparative Examples 1 to 3 is measured. As in 2 1, a space of a surveillance gate is divided from the ground to the gate inlet at heights of 39, 65, 93, 120 and 135 cm and from the gate center in the width direction at intervals of 10 cm. Then each magnetic label is allowed to pass through the gate in the room to check whether the system detects the magnetic label or not. This is a magnetic label 1 which is a soft magnetic material 3 (Metal wire, tape and the like), arranged and measured in the longitudinal direction, transverse direction and vertical direction with respect to the gate (the corresponding directions are in 3 shown), as on the left side, the middle and the right side in 3 shown. The measurements are made twice when the material enters the gate and when it leaves the gate. The detection sensitivity of the magnetic label 1 is evaluated by a ratio (%) obtained by taking the number of magnetic label acquisitions 1 divided by the system by the total number of passes of the label through the gate. The results obtained by the Sensormatic system are shown in line (A) in Table 1, and the results obtained by the Esselte Meto system are shown in line (B) of the table.

As shown in Table 1, in Comparative Example 3, which has no discontinuous and sudden magnetic reversal, the sensitivity measured by the Sensormatic system is low. In Comparative Example 1 where a discontinuous and sudden remagnetization is observed and the magnetic field exceeds 0.2 Oe, the sensitivity measured by the Esselte Meto system is obviously low. With respect to Comparative Example 2, even if the magnetic field is less than 0.2 Oe, the magnetic flux change radiated at the time of magnetic reversal is smaller than 8.0 × 10 ^-9 Wb, and the comparative example is insufficient in both systems of Sensormatic and Esselte Meto Sensitivity on. In contrast, Examples 1 to 5 as a magnetic label according to the present invention, where in a smaller magnetic field than 0.2 Oe, a discontinuous and sudden remagnetization occurs and the magnetic flux changes in the remagnetization are greater than 8.0 × 10 ^-9 Wb , in both systems of Sensormatic and Esselte Meto sufficient sensitivity. Here, for Example 3, where the magnetic field changes by more than 0.1 Oe, the sensitivity of the label in the Sensormatic system is lower than in the other examples.

The The invention may be practiced in various ways without departing from its spirit To depart from the basic idea. Although the invention is in connection with their above embodiments Completely has been described, it is explained only by way of examples, and the invention is not limited thereto. The scope of the present Invention is by the attached claims defined, and various modifications that are within the claims, are to be understood as included in the scope of the invention.

Claims (10)

Magnetic label containing a soft magnetic material ( 12 . 14 . 18 ), wherein the soft magnetic material is inserted between two paper or plastic foil layers, wherein the magnetic label has a length greater than or equal to 70 mm, wherein the soft magnetic material ( 12 . 14 . 18 ) generates a sudden remagnetization with a magnetic flux change of not less than 8.0 × 10 ^-9 Wb when an external alternating field having a magnetic field strength in the range of 0.03 Oe up to a maximum field is applied, the maximum field being a coercive force of soft magnetic material, and wherein the soft magnetic material has a fluctuation within 0.1 Oe of the magnetic field strength at which the sudden remagnetization occurs. A magnetic label according to claim 1, wherein the soft magnetic Material the sudden Magnetic reversal generates when the magnetic field strength fluctuates by an amount which is less than or equal to 0.1 Oe. A magnetic label according to claim 1, wherein an amount of the magnetic flux radiated around the soft magnetic material as a concomitant of the sudden remagnetization is not smaller than 8.0 × 10 ^-9 Wb. A magnetic label according to claim 1, wherein the soft magnetic material is a difference between Signal amplitudes at 1.5 kHz and 3.5 kHz, which is smaller than -3 dBm, when a sinusoidal magnetic field with an amplitude of 1.5 Oe at a frequency of 73 Hz is applied. A magnetic label according to claim 1, wherein the soft magnetic Material is a wire. A magnetic label according to claim 1, wherein the soft magnetic Material is a band. A magnetic label according to claim 1, wherein the soft magnetic Material a thin film is. A magnetic label according to claim 1, wherein two Types of the soft magnetic material are arranged in contact with each other become. A magnetic label according to claim 1, wherein the soft magnetic Material of wire or a thin film on the as a thin film executed soft magnetic material is arranged. The magnetic label of claim 1, further a hard magnetic material having a coercive force greater than that of the soft magnetic material, wherein the hard magnetic Material arranged in close contact with the soft magnetic material is.