DE19617582A1 - Deactivatable security strip and method and device for producing a deactivatable security strip - Google Patents

Description

The invention relates to a deactivatable fuse stripes, especially for article surveillance in Department stores made up of a soft magnetic strip given length, when applying a magnetic Alternating field to deliver a characteristic signal is excited, and sections of a defined length semi-hard or hard magnetic material, which arranged with respect to the soft magnetic strip are that they are the characteristic signal in the saturated state of the soft magnetic strip. Furthermore The invention relates to a method and an apparatus for Production of such a security strip.

Soft magnetic, activatable material (e.g. Permalloy) is characterized by a high permeability and a low Coercive force and is located in the surveillance zone of the / Exit area of a department store by a magnetic Alternating field for the emission of a characteristic signal excited. This signal is subsequently from an im Frequency range of the signal sensitive detector device detected and as an identification signal for one in unauthorized  Evaluated goods passing through the surveillance zone; on The alarm is triggered.

Of course, the detector device should no longer address as soon as the goods have been properly paid for. The semi-hard or hard magnetic serve this purpose strip-shaped sections. Semi-hard or hard magnetic Material has the opposite properties of soft magnetic material: it is characterized by a low permeability and a high coercive force. Due to the high coercive force, the deactivator material in the non-deactivated state by the alternating magnetic field not affected in the surveillance zone. As soon as that Deactivator material, however, by a correspondingly high Magnetic field is driven into saturation - what after proper payment for the goods is made - prevents his Magnetization is a reaction of the soft magnetic material to the alternating magnetic field in the monitoring zone.

Deactivable security elements are available in large quantities used. Since each securing element is usually only once is used for article security, is a special one Attention to cost-effective production.

DE 42 23 394 A1 already describes a method for Manufacture of security labels became known that the following manufacturing steps: on a non-metallic Tape become a hard magnetic metal strip and then on an elastic carrier foil is glued onto the metal strip. The Carrier film is so thick and flexible that the deformation the metal strip through a rotating punch knife is sufficient to separate the metal strip into sections to separate. The separated sections of the metal strip and the non-metallic tape are removed from the carrier film peeled off, and on the remaining parts of the metal strip a soft magnetic tape is then applied. Around Making a finished label tape is - as is common usual - on one side of the tape label paper and on the other side, a carrier tape is glued on.  

Without a doubt, this well-known process is best for the provision of large numbers of securing elements suitable. However, the relatively high level is less satisfactory Effort involved in the manufacture and application of the semi-hard or hard magnetic sections on the soft magnetic Strip must be operated.

The invention is based, an inexpensive task and easy to implement deactivatable backup strip, as well as a method and a device, the one inexpensive and simple manufacture of a deactivatable Allow security strips to suggest.

The object is achieved with respect to the security strip in that the semi-hard or hard magnetic strip is treated periodically at a predetermined distance a successive sections of a predetermined length b by supplying energy in such a way that the component of the remanent magnetization M _r ¹ in parallel in the treated sections to the longitudinal direction (: = preferred direction) of the semi-hard or hard magnetic strip is less than the component of the remanent magnetization M _r ° in the intermediate, untreated sections. This fact can be described mathematically by the inequality: M _r ° ≷ M _r ¹ or M _r ° / M _r ¹ ≷ 1.

According to an advantageous embodiment of the security strip according to the invention it is provided that the saturation magnetization M _s in the sections parallel to the preferred direction of the semi-hard or hard magnetic strip goes to zero.

An alternative embodiment, which can certainly be used in connection with the first-mentioned embodiment, provides that a uniaxial anisotropy K _u 1 is induced transversely to the preferred direction of the semi-hard or hard magnetic strip in the treated sections.

The object is achieved with respect to the method for producing a security strip according to the invention in that energy is supplied periodically at a distance a from one another to sections b of the length b of the semi-hard or hard magnetic strip, the energy supply being dimensioned such that the strip in the treated sections has a Component of the remanent magnetization M _r ¹ in the preferred direction of the semi-hard or hard magnetic strip, which is less than the component of the remanent magnetization M _r ° in the intermediate, untreated sections.

According to an advantageous development of the invention The method provides that the periodically in one predetermined distance between successive sections Power supply to be heated electrically. This configuration the method is extremely simple to implement and allows in addition, a high working speed.

An inexpensive and reliable design of the inventive method suggests that the temperature in the treated sections is monitored and that the Circuit is broken once treated in the Sections a predetermined temperature is reached. Apart from the fact that there is a non-contact temperature measurement via a radiation detector very easily and with high Temperature measurement can be used to achieve accuracy of course also ideally suited as an indicator for to indicate if that was originally semi-hard or hard magnetic material its physical properties changed according to the invention.

The treatment process is ended in a simple manner by that the circuit is broken. This can be done achieve that the strip is lifted off the contact heads and / or in that the control device is the power source turns off.  

It is particularly advantageous accordingly Further development of the method according to the invention to consider that the strip with the semi-hard or hard magnetic sections and the treated sections immediately after that soft magnetic tape material is applied. By the immediate bonding of semi-hard or hard magnetic and Soft magnetic tape material can be very thin Manufacture security strips, which is particularly the case with the so-called Source integration, if the security strips in the securing goods are implemented, of great importance is.

In addition to the electrical energy supply, it is according to one advantageous development of the method according to the invention also possible that the sections of length b laser energy is fed.

It has proven to be particularly advantageous if a magnetic field with at least the anisotropy field strength H _k , with H _k = 2K _u ° / M _s °, is applied during the supply of energy to the sections of length b, the direction of the magnetic field being approximately perpendicular to Preferred direction of the semi-hard or hard magnetic strip is. The anisotropy field strength H _k is the field strength that is required to saturate the material transversely to the preferred direction.

The same effect can also be achieved in that the Sections of length b during the energy supply with a mechanical tension (tension or pressure) can be applied. Again, the tension is such that in the treated sections a stress-induced anisotropy perpendicular to the preferred direction of the semi-hard or hard magnetic strip is generated.

With regard to the device, the task is thereby solved that several spaced apart a Treatment stations are provided covering the sections of the Length b of the semi-hard or hard magnetic tape material  Supply energy, and that at least one control device provided the energy supply in the treated sections and controls the feed of the strip material.

The treatment stations are advantageously by two contact heads arranged at a distance b, which with are connected to a power source, each of which treating section forms part of the circuit.

According to an advantageous embodiment of the invention Device are on the side of the tape material that the Contact heads are opposite to the contact heads Corresponding pressure elements provided that the Tape material during the treatment period against the Press contact heads.

As mentioned earlier, an as Radiation detector (photodetector) is provided, the temperature of the sections without contact detected.

According to an advantageous development of the invention A pair of rollers is provided, which is intermittent is driven and the strip material between the Contact heads and the pressing elements moved through.

The invention is illustrated by the following figures explained. It shows:

Fig. 1 is a perspective view of an invention, deactivatable security strip,

Fig. 2a shows a perspective view of a conventional semi-hard or hard magnetic strip,

FIG. 2b shows a typical hysteresis curve of the semi-hard shown in Figure 2a or hard magnetic strip.,

Fig. 3a shows a perspective view of a fuse element according to a first embodiment,

FIG. 3b is an illustration of a typical hysteresis curve along the preferential direction of the treated portions of the, in FIG. 3a constitute strip

Fig. 3C is a schematic representation of the course of the stray field Hs in which in Fig. 3a illustrated strip (longitudinal section through the strip 1),

FIG. 4a is a perspective view of a fuse element according to a second embodiment,

FIG. 4b is a representation of a typical hysteresis curve along the preferential direction of the treated portions of the, in Fig. 4a constitute strip

Fig. 4c is a schematic representation of the course of the stray field H _s in which, in Fig. 4a illustrated strip (longitudinal section through the strip),

Fig. 5 is a schematic representation of a manufacturing process for securing strip, in which the device and method according to the invention is integrated,

Fig. 6 is an illustration of an embodiment of the device according to the Invention and

FIG. 7 shows a flowchart for controlling the control device 19 for the device shown in FIG. 5.

A perspective view of a deactivatable security strip 1 can be seen in FIG. 1. The deactivatable security strip 1 consists of a soft magnetic strip 2 onto which a semi-hard or hard magnetic strip 3 is laminated. The structure and the properties of the semi-hard or hard magnetic strip 3 have been changed periodically at intervals a successive sections 4 b by the supply of energy. The power supply according to the invention has the effect that in the treated sections 4 b, the original physical properties of the semi-hard or hard magnetic strip has changed. The original, physical properties of the semi-hard or hard magnetic strip 3 can thus only be found in the untreated sections 4 a.

FIG. 2a shows a perspective illustration of a conventional semi-hard or hard magnetic strip 3 with the remanent magnetization M _r °. As a result of the manufacturing process, the strip 3 shows a remanent magnetization M _r ° and an anisotropy K _u ° in a preferred direction. In the case shown, the preferred direction is in the x direction.

FIG. 2b shows the hysteresis curve of the semi-hard or hard magnetic strip 3 shown in FIG. 2a, that is to say the change in the magnetization M as a function of the field strength H of the external magnetic field. SEMIVAC, which is sold by Vacuumschmelze, is an example of a semi-hard magnetic material.

In Fig. 3a is a perspective view of a first embodiment is illustrated of the semi-hard or hard magnetic strip 3 according to the invention. The semi-hard or hard magnetic strip 3 shows sections 4 b of length b, which are arranged at a distance a from one another. Sections 4 b have been subjected to a heat treatment and have changed their magnetic properties as a result of this heat treatment.

As can be readily seen from a comparison between the two figures Fig. 2b and FIG. 3b, the remanent magnetization M _r in the treated portions 4 b is diminished compared to the corresponding sections in the untreated state. The desired result sought and realized by the invention is achieved if - mathematically expressed - the following condition is fulfilled: M _r ° ≷ M _r ¹, M _r ° / M _r ¹ ≷ 1. In this embodiment, therefore, only Magnetization M in the treated sections 4 b changed. However, like the untreated sections 4 a, they continue to have a uniaxial anisotropy K _u ° parallel to the preferred direction (here: x direction).

Fig. 3c shows a longitudinal section through the illustrated in Fig. 3a strips 3 according to the invention. In particular, the magnetic field profile can be seen from this figure. As a result of the different remanent magnetizations M _r ° and M _r ¹ in the treated sections 4 b and the untreated sections 4 a, stray fields occur. In the ideal case, the untreated sections 4 a show a physical behavior as if there was no material (or air) between the treated sections 4 b. The same effect is thus achieved, which the previously known security strips with spaced deactivator sections also show.

Fig. 4a shows a second embodiment of the strip 3 according to the invention in a perspective view. As a result of the energy supply to the sections 4 b when in the figures Fig. 3a, Fig. 3b and 3c embodiment shown Fig., Only the remanent magnetization M _r was affected is here additionally b uniaxial anisotropy K in the treated portions 4 _u ¹ generated perpendicular to the preferred direction (here: x direction). The untreated sections 4 a also show the original anisotropy K _u ° of the semi-hard or hard magnetic strip 3 . This can be achieved by applying a magnetic field H during the energy supply to sections 4 b. The applied magnetic field H should have at least the anisotropy field strength H _k = 2K _u ° /, M _r °. As already mentioned, the anisotropy field strength H _k is the field strength that is necessary in order to overcome the anisotropy in the preferred direction in the treated sections 4 b and the uni-axial anisotropy K _u 1 transverse to the preferred direction of the semi-hard or hard magnetic in the treated sections 4 b To strip 3 .

As is apparent from the figures, Fig. 4b and Fig. 4c, the effect of this embodiment of the security strip 1 according to the invention in terms of the remanence (component of the remanent magnetization) in the preferred direction or the path of the stray field H _s is equivalent to the in the figures Fig. . 3c embodiment 3a, Fig. 3b and Fig illustrated.

Fig. 5 is a schematic illustration showing a manufacturing process for a securing strip. The device according to the invention and the method according to the invention are integrated into this manufacturing process.

The soft magnetic strip material 2 is unwound from a roll 5 and stored in a buffer device 7 . The soft magnetic strip material 2 is guided into the device 10 via a deflection roller 9 . In this device 10 , one side of the soft magnetic strip material 2 is coated with adhesive.

The semi-hard or hard magnetic strip material 3 is also unwound from a roll 6 and stored in a buffer device 8 . In the device 11 according to the invention, the semi-hard or hard magnetic tape material 3 is divided into individual sections 4 and then glued onto the soft magnetic tape material 2 at a distance b. The security strip 1 is dried in the dryer 12 ; Finally, the dried security strip 1 is wound onto the roll 14 , a buffer device 13 being interposed, which compensates for differences in the tensile stress acting on the security strip 1 .

In FIG. 6, an embodiment of the device 11 according to the invention. The semi-hard or hard magnetic strip material 3 is passed step by step by means of the pair of rollers 19 between the contact heads 15 , 16 and the pressing elements 22 opposite them. The right contact head 16 of a pair or the corresponding pressing element 22 is arranged at a distance a from the left contact head 15 or the corresponding pressing element 23 of the subsequent pair.

When the desired position of the strip material 3 is reached , the control device 20 moves the pressure elements 22 and the contact heads 15 , 16 together until an intimate contact is established between the contact heads 15 , 16 and the strip material. The power supplies 17 are then activated. The current flowing between the contact heads 15 , 16 heats the sections 4 b of the strip material 3 until its originally semi-hard or hard magnetic properties have changed according to the invention. Since a certain temperature must prevail b in sections 4 for this physical change process, the achievement of a predetermined temperature is used as indicator for the fact that the conversion process has been completed. The temperature in the treated sections 4 b is advantageously determined in a contactless manner by means of radiation sensors 18 (photosensors). The temperature values are forwarded to the control device.

As soon as the predetermined temperature is reached, the control device 20 causes the contact heads 15 , 16 and pressing elements 22 and 23 to move apart. The control device 20 then rotates the pair of rollers 19 further by an angle α which corresponds to the distance n * (a + b) and the previously described method steps are repeated. The information about the angular position is supplied by the angle encoder 21 , which is attached to the axis of one of the two rollers 19 a, 19 b. The rotary movement of the two rollers 19 a, 19 b of the pair of rollers 19 is preferably coupled via gearwheels not shown separately in the drawing. The strip material 3 with the semi-hard or hard magnetic sections 4 a and the treated sections 4 b is then laminated directly onto the soft magnetic strip material 2 , which is fed via the roller 19 b.

FIG. 7 shows a flowchart for controlling the control device 19 for the device shown in FIG. 5. After starting the program at 24, the contact heads 15 , 16 and the corresponding pressing elements 22 , 23 are moved together according to the program points 25 and 26 until an intimate contact is made between contact heads 15 , 16 and strip material 3 - which after covering the path x Case is. At 27 and 28 , the current sources 17 are activated until the predetermined target temperature T setpoint is reached in the treated sections 4 b. The contact heads 15 , 16 and the pressing elements 22 , 23 are then moved apart by the distance x at 29 and 30 . Now the strip material 3 is moved according to the program points 31 and 32 by the distance 3 · (a + b); this distance corresponds to a rotation of the rollers 19 a, 19 b of the pair of rollers 19 by the angle α. As soon as the rotation through the angle α has been carried out, the program jumps back to point 25 and the cycle repeats.

Reference list

1 security strip that can be deactivated
2 soft magnetic strips
3 semi-hard or hard magnetic strips
4 a semi-hard or hard magnetic section
4 b treated section
5 roll
6 roll
7 buffer device
8 buffer device
9 deflection roller
10 adhesive feed device
11 Device for the production of security strips
12 dryers
13 buffer device
14 roll
15 contact head
16 contact head
17 Power supply
18 radiation sensor
19 pair of rollers
19 a roller
19 b roller
20 control device
21 angle encoder
22 pressing element
23 pressing element.

Claims (14)

1.Deactivatable security strip, in particular for article security in department stores, which consists of a soft magnetic strip of a given length, which is stimulated to emit a characteristic signal when an alternating magnetic field is applied, and sections of a defined length of a semi-hard or hard magnetic material which consists of the soft magnetic strips are arranged such that they suppress the characteristic signal of the soft magnetic strip in the saturated state, characterized in that
that the semi-hard or hard magnetic strip ( 3 ) is treated periodically at a predetermined distance (a) successive sections ( 4 b) of a predetermined length (b) by supplying energy in such a way that in the treated sections ( 4 b) the component of remanent magnetization (M _r ¹) parallel to the longitudinal direction (: = preferred direction) of the semi-hard or hard magnetic strip ( 3 ) is lower than the component of the remanent magnetization (M _r °) in the intermediate, untreated sections ( 4 a). 2. Security strip according to claim 1, characterized in that the saturation magnetization (M _s ) in the treated sections ( 4 b) parallel to the preferred direction of the semi-hard or hard magnetic strip ( 3 ) goes to zero. 3. Security strip according to claim 1, characterized in that in the treated sections ( 4 b) a uniaxial anisotropy (K _u ¹) transverse to the preferred direction of the semi-hard or hard magnetic strip ( 3 ) is induced. 4. Process for the production of deactivatable security strips, in particular for article security in department stores, a deactivatable security strip consisting of a soft magnetic strip which carries sections of a certain length from a semi-hard or hard magnetic material at defined intervals, characterized in that periodically at a distance (a) successive sections ( 4 b) of the length (b) of the semi-hard or hard magnetic strip ( 3 ) energy is supplied, the energy supply being dimensioned such that the strip ( 3 ) in the treated sections ( 4 b) is a component the remanent magnetization (M _r ¹) in the preferred direction of the semi-hard or hard magnetic strip ( 3 ), which is less than the component of the remanent magnetization (M _r °) in the intermediate, untreated sections ( 4 a). 5. The method according to claim 4, characterized in that the periodically in the predetermined distance (a) successive sections ( 4 b) are electrically heated by supplying electricity. 6. The method according to claim 4 or 5, characterized in that the power supply to the periodically spaced (a) successive sections ( 4 b) of the semi-hard or hard magnetic strip ( 3 ) is interrupted as soon as in the treated sections ( 4 b) a predetermined temperature has been reached. 7. The method according to claim 4, characterized in that the sections ( 4 b) laser energy is supplied. 8. The method according to claim 4, 5, 6 or 7, characterized in that a magnetic field with at least the anisotropy field strength (H _k ) with H - 2K _u ° / M _s ° is applied to the sections ( 4 b) during the energy supply, the direction of the magnetic field being approximately perpendicular to the preferred direction of the semi-hard or hard magnetic strip ( 3 ). 9. The method according to claim 4, 5, 6 or 7, characterized in that a mechanical tension is applied in the sections ( 4 b) during the supply of energy, which is dimensioned such that the voltage-induced anisotropy perpendicular to the preferred direction of the originally untreated, semi-hard - Or hard magnetic strip ( 3 ). 10. Device for producing a deactivatable security strip, in particular for article security in department stores, the deactivatable security strip consisting of a soft magnetic strip which carries sections of a certain length from a semi-hard or hard magnetic material at defined intervals, characterized in that
that a plurality of treatment stations ( 15 , 16 , 17 ) arranged at a distance (a) from one another are provided, which supply energy to the sections ( 4 b) of the length (b) of the semi-hard or hard magnetic strip ( 3 ), and that at least one control device ( 20 ) is provided, which controls the energy supply to the sections ( 4 b) of the semi-hard or hard magnetic strip ( 3 ). 11. The device according to claim 10, characterized in that it is at a treatment station ( 15 , 16 , 17 ) each two spaced (b) contact heads ( 15 , 16 ) which are connected to a power source ( 17 ), the circuit being closed by contact with the semi-hard or hard magnetic strip ( 3 ). 12. The apparatus of claim 10 or 11, characterized in that pressure elements ( 22 , 23 ) are provided which face the contact heads ( 15 , 16 ). 13. The apparatus according to claim 10, characterized in that a working as a temperature sensor radiation detector ( 18 ) is provided, which detects the temperature of the sections ( 4 b). 14. The apparatus according to claim 11 and 12, characterized in that a pair of rollers ( 19 ) consisting of rollers ( 19 a, 19 b) is provided, which is driven intermittently and thereby the strip ( 3 ) between the contact heads ( 15 , 16 ) and the pressing elements ( 22 , 23 ) are moved through.