DE2156103A1 - Magnetically encoded documents, in particular credit cards, and methods of production - Google Patents

Description

Minnesota Minina and Manufacturina Company,

3M Center, Saint Paul, Minnesota 55lol / V.St.A.

"Magnetically encoded document, in particular credit card, as well as method for producing"

Priority: November 12th, 1997; V.St.A .; No. 88,621

The invention relates to a magnetically encoded document, how it can be used, for example, as a credit card, as well as a method for maonetic coding of such a card Document.

Magnetically encoded documents of this type are known (e.g. U.S. Patents 3 ol5,087, 3,430,2oo, 3,453,598, 3,465,3o7, and 3,471,862). These known documents contain magnetizable ' Material. These documents are coded either by

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that this material is maanetized in discreetly distributed places and so Maanetisierunaszone different polarity arise, which a predetermined two-dimensional pattern on the Determine the document surface, or by distributed arrangement of maanetized material for the production of a permanent one two-dimensional pattern of such maanetized zones. In one known document, for example, barium ferrite particles are used used in a base material made of rubber or plastic. Such a material can be magnetized and retains its magnetization long enough for such a material to be considered magnetic hard material can be called. Magnetically hard material is defined as a material with a large coercive force and thus great resistance to demagnetization.

The known methods for coding such documents require relatively complex systems and devices. With the known Documents also run the risk of being easily coded lose, i.e. the Maanet areas are deleted or changed. The individual data can be taken from the known documents in addition, only be able to read the abaeles through complicated systems and there is a risk of incorrect reading.

It is therefore the task of the invention, a new naanetic To create a coded document that is particularly suitable as a credit card and that no longer has the disadvantages of the previous one Owns documents of this type and also encodes them in a simple manner can be. Furthermore, it is the task of the invention to

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ches ^ learn how to encode such documents, as well a simple apparatus for carrying out such a process.

According to the invention, this requirement is resolved based on the prior art mentioned above by a mechanically encoded document according to the ^first main claim. Advantageous further developments of this document as well as details about the method for carrying out such a coding and the device for this emerge from the subclaims and the following description.

In an inventive document in which the limit
between the differently polarized sections need not necessarily run through the oanze layer, although
This is mainly the case, the magnetic areas cannot be easily erased or changed and they are in the
essentially insensitive to Maonet fields, which run in the plane of the document, since the main axis of the magnetic material, i.e. the axis, in which way the maanetic material can easily be maanetized and reversed, perpendicular to the
Document layer runs and the Paterial also in this
Main axis is maanetized. A document according to the invention also has a significantly larger number of coding possibilities per line areaization area than the known documents. Since two oppositely dimensioned sections with an intermediate boundary are provided for each cornice area, creating a cornice field to the end of the angle

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*> ..>.:. ■■■■ - ■ ';:. ** ■ 8ADORiGINAt

this boundary geaen across the broadside of the layer, if not one Coding stamp according to the invention is used, the form of the Sections of the area changed and probably also the position the limit with respect to the middle of the area is eliminated or changed. If there is still one border section left, it can be Skew angle in the layer probably no longer correct by the display device for determining this alignment to be established. This avoids counterfeiting. the Orientieruna the border between the entaeaenet polarized Sections is very precisely and sharply defined, and better than, for example, the orientation of a dipole in a particular one Section of the document and this makes the evaluation more precise and precise.

The invention is illustrated below with the aid of schematic drawings explained in more detail using examples.

Fig. 1 shows a mechanically encoded according to the invention

^ dit card with imprint;

Fig. 2A and Fin. 2B show such cards with two possibilities for the maanetic coding, with the top layer partially removed;

Figures 3A through 3C show further courtesies for training the individual Maanet areas on the map;

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Fig. 4 shows a device for manual reading of such a device Map;

Fig. 5 and Fig. 6 show details of this viewing device, 6 are sections .long the line 6-6 of FIG. 4;

Fig. 7 and 8 show a stamp for manual coding of such a card according to FIGS. 1 and 2.

Fig. 1 shows a credit card Io, on top of which 12 the Name of the operating company as well as the name, address and the account number is recorded as an endorsement v / earth on the card Io, for example, printed, punched, embossed or in a combined embossing and printing process upset.

According to FIG. 2Λ from a document or Layer 14 made of magnetically hard material. This layer 14 consists, for example, of a continuous base einaxia anisotropic mannetically hard barium ferrite particles that

in

in a binder or / a base material made of rubber, plastic or another non-macmetic material. A perrranent Maanetisches material is preferably used, that in the brochure "Flastiform Brand Permanent Maanets", Dielectric. Materials & Systems Division of Minnesota Minina and

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- D ~

Manufacturina Copoany, St. Paul, Minnesota. The layer 14 contains permanent manure material whose Maanetisierunasachse, i.e. the axis in which the Maanet can be easily magnetized or grounded with reversed polarity, perpendicular to the surface the layer 14 is oriented. The permanent maanet material is also maanetised in the direction of this Maanetisierunasachse.

The thickness of the card was about 0.75 mm. The residual induction B of the naanetized material in the magnetized areas 16 is about 2,000 gauss. The mechanical attractions in the maanetized areas 16 of the card Io can still thereby be increased so that on the side of the layer 14 opposite the surface 21 a reinforcement made of steel is provided v / ird.

A predetermined permanent two-dimensional structure is created on the layer 14 by a multiplicity of differently magnetized regions 16 Pattern determined. The maanetized areas 16 each consist of zv / egg magnetized sections 18 and 19, the in the drawing with N and S respectively for the Maanetic murder pole and the magnetic south pole, namely on of the surface 21. The sections 18 and 19 are in the first place invisible to the naked eye when the layer 14 is viewed directly.

In the case of the Firr, 2Λ card, layer 14 is only imperceptible limited, with the exception of Sections 18 and 19, which each

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v; eils rit? I and S are designated.

In the map according to FIG. 2B, the sections 2o are naanetized, namely with a maanetic south pole on the surface 21 of the Layer 14. The remainder of Layer 14 has north polarity on the Surface 21.

With both maps according to FIGS. 2Λ and 2B, the naanetische polarity on the surface 21 of the layer 14 entoeaengesetzt i of the magnetic polarity of the upper side, since the Pernanentnaanetnaterial is naanetisiert in Richtuna the nacinetischen axis 21 aegenüberliegenden back of the layer 14 which extends to the layer senkrocht fourteenth

Each oppositely polarized pair of sections 18, 19 has a boundary 22 which extends across the width of the layer 14 runs. The angles at which the boundaries 22 run transversely to the layer 14 reproduce the respective data, namely is a certain angle in each case characterizing predetermined dates.

In the exemplary embodiment shown, the limits are 22 arranged in five different angular positions transversely to layer 14. A comparison of the top row 24 of pannetized areas ] 6 shows nit the lower row 26 "of the naanetized areas 16, that although the angles of the boundaries 22 in neighboring Maanetisierunas areas 16 of these two rows 24 and 26 are the same, but that the laaen of the polarities of the individual sections (II, S) in bezun on the limits 22 are different. By changing the rela-

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are Tivon Lane eggs Marrnetisierunnsbereiche M and S in bezua to the boundaries 22 can thus the number of different data daraestellt should v / ground doubled aegenüber the number of data, the ground only by the angle] μ te lluna wiederaeaeben v /. In the map according to FIG. 2Λ the boundaries 22 are arranged in five different angular positions and because of the inderuna of the Laae of the polarization of the aeaenüberüberlager sections in relation to these boundaries 22 ten different data are reproducible.

In the case of the map according to FIG. 2B -are the straight boundary lines of the semicircular sections 2o the boundaries 23 which intersect the mechanical areas through which the predetermined two-dimensional cough is determined.

Assume the angles of the boundaries 22 and the Laae of the magnetic areas N and S with respect to these boundaries of the embodiment according to FIG. 2A determine the numbers 1, 2, 3, 4, 5, 6, 7, 8, 9, O. If you put the rows 24 and 26 consecutively

^ reads from left to right, the angles correspond to Boundaries 23 and the Laae of the mechanical sections 2o in relation to these boundaries 23 in the embodiment according to FIG. 2B Numbers 4, 5, 6, 8,, o, 2, 1, 9, 3, 7.

In the context of the invention, it is also possible that none, but not all, maanetized areas of the map Sections of entaeaene attached polarization and one in between are provided diagonally to the map border, but that

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the card .10 is maanetized that it is in a certain surface the layer only has a raanetic polarization, for example only cord or south polarization, on v / eist, or sonar unpagnetized is. Further coding possibilities arise on this keisp.

The layer 14 can consist of a single-axis anisotropic material which is arranged with its easily umoolable magnetic axis in the broad plane of the layer 14. However , other uniaxially anisotropic or sonically unoriented materials can also be used and / or the mechanically hard material of layer 14 can be magnetized in the plane of layer 14 instead of perpendicular thereto, so that oppositely maanetized sections 18 and 19 according to FIG. 3Λ, 3B and 3C arise, in which the direction of the magnetic field is indicated by the arrows.

The visualization of the codes applied to the card can be done with a Maonetic sight 3o Viewer 3o according to FIG. 4 again makes the data visible, ™ by the direction of magnetic polarization at each of the numerous distributed areas are determined. This device includes a transparent board 32 in which a plurality of sockets 33 are arranged in a corresponding to the predetermined pattern Distribution. Disks 35 are arranged therein which have mechanically hard material that is magnetized in this way is that en has a predetermined direction of polarization. Every Disk 35 also includes a visual display the direction of polarization of this disk. Any of these fisiinetics

- lo / -

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- Io -

Panes are made by the abrcssunaen of the base 33 within this base 33 aehalten and it is so bewealich within this base 33 that it can occupy a Laae, the the mechanical polarization direction? in one of the fiaanetisierunas areas 16 corresponds.

The mechanical disks 35 are grounded in the base 33 by a transparent lower surface 36 and a transparent cover layer 37 stop. As a result of the transparency of the observation device 3o according to FIG. 4, the can be imprinted on the card Read visas, e.g. urine and account number, while at the same time the mechanically coded data is viewed and read.

The disks 35 are made from the same material as an axially anisotropic, mechanically hard permanent material like layer 14 of the card Io. The permanent magnet material of the disks 35 is oriented so that again the main magnetic axis at right angles to the flat surface 39 of the disks 35.

More examples for the training of these Maanet discs 35 show Figures 5Λ and 5B.

The disks 35 are maanetized so that they are on their surface 39 each aeaen over the different α. · Ι 'drb "ccr. Areas 4o and 42 are two male regions of entangled polarity with

- 11 / "

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have a boundary between them. A visual indicator 46 corresponding to this limit is applied to each disk 35 on the surface 47 which overlaps the surface 39, whereby the direction of the limit and the length of the entaeaeanized oolarized Macnet sections in relation to this limit is shown. In the case of the disk according to Fin. 5Λ, a two-color layer 48 of reflective material is provided as a visual indicator 46 for the border. The display 4 6 is determined by the border line of the two colors, which corresponds to the Laae of the border. The light-colored “reflection material area 42 indicates one polarity of the raanetic surface, for example the naane ti see north pole of the underlying surface 47, the darker-colored reflection material area 40 indicates the surface of the magnetic polarity set, for example the maonetic south pole on the underlying surface 47 The lighter colored material, which thus indicates a mechanical north pole under the area 4 2 of the surface 47 of the disk, which advises a reflective material section 42 is covered, thus shows in an inverse way a mechanical south pole in section of the flat surface 39, which is the Area 42 aeaenüberlieat.

The direction of the border and the Laae of the differently polarized Sections relating to this limit are in yours. Execution for Dxel marked by an arrow 46 according to FIG. 5B. This arrow 46 is preferably either parallel (according to Fig. 5B) or perpendicular to this limit.

- 12 / -

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The magnetic disk according to FIG. 5Λ can for example se like folate first of all the visual indicators are grounded on a Sheet of magnetically hard material attached, which is a magnetic Has major axis perpendicular to the broad plane. This leaf is then pressed into contact between a seroentine-shaped Arranges copper wire and a steel plate in such a way that the copper wires coincide with the displays. Then a electric current impulse by discharging a capacitor battery sent through the wire, so that polarized opposite Magnetic areas are created, the limits of which coincide with the position of the copper wires. Then this sheet becomes the Discs punched out so that they finally maanetized opposite to one another Have areas on its surface on either side of the display.

If the card Io is brought together with the display device 3o, so that the mechanical areas coincide with the bases 33, so diejeniaen discs 35 in the sockets 33 with the Areas 16 which polarized a boundary 22 between entaeatesets Sections 18 and 19 have, try to occupy a position in which they lie flat within the base 33 and its indicator 46 runs parallel to the boundary 22 of the layer] 4. The lane of the discs 35 in the device 3o corresponds to the position of the discs, which occurs when the device 3o with a card according to Pia. 2Λ is brought together.

6Λ and 6B show that the base 33 has such a di-

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bath

Have mcnsion that the discs 35 cannot tip over. To Fin. 6Λ takes a disc 35 a flat plane Stelluna in base 33 a if never has a crernse 22 between sections 18 and

19 offset polarity on the surface of the layer 14 of the card Io, while FIG. 6B shows that the disk 35 in the base 33 assumes a slightly tilted oblique position when it is brought over a maanet area that is only a single one mechanical polarization on the surface of layer 14 of the

Has map Io.

The number of Haanet areas must be 16 on the Io card does not necessarily correspond to the number of sockets 33 in the device 3o. The number can be chosen arbitrarily, but the predetermined pattern of the magnetic areas 16 must match the predetermined Pattern of the socket 33 match.

, 19th

The magnetic coding of sections 18 / of opposite magnetic polarization is preferably carried out as follows. 7 and 8, the card Io is written on a sheet 5o made of iron or soft steel, and two enteaeets magnetized pole piece faces 51, 52 of a magnetic punch 54 are grounded in contact with the surface 12 of the card Io a brought. The punch 54 consists of two pole pieces 58 and 6o made of iron or VJeichstahl. Between these pole pieces is a tapered Permanentnuianet 62 arranged, for example made of the same material as the layer 14 and the disks 35. "If the stamp 54 with the card Io is put in Rerühruna,

- 14 / -

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the surface 21 of the layer 14 is magnetized so that it two nacmetized sections 18 and 19 in one place Border between them, which corresponds to the gap 64 between the surfaces 51 and 52, which are brought into contact with the card Io.

The same procedure can be used to encode a card Fig. 2B can be used provided that the layer. 14 is first magnetized uniformly, in one direction perpendicular to the layer.

This magnetization step can also be carried out without using a sheet of iron or mild steel in contact with the card Io carried out v / earth.

- Requests -

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Claims (7)

- 15 claims \ J Maanetisch encoded documentary Rent, in particular credit card, / eidir are in a layer of hard material Farrnetisch at v / hich in a distributed zv ^ ensionalen f'uster regions of different polarity, characterized aekennzeichnet that rintiestenr. on the one surface (21) of this layer (14) each individual area (16) has sections (18, 19; 20, 21) separated from one another by a boundary (22, 23) with entranced rcaanetic polarity, the angular cells of this Boundary (22,23) on layer (14) is characteristic of the various data. 2. Document according to claim \, characterized in that the layer (14) consists of einaxio anisotropem Raanetic hard * Ilaterial, whose main naanetic axis is oriented perpendicular to the layer plane and which is nannetized in Richtunn this axis. 3. Document according to claim 1 or 2, characterized in that in addition to the Winkellaae of the border (22, 23) also the Laoe of the respective polarity of the sections (18,19; 2o, 21) in relation to this limit for the data is characteristic (different Polarity of lines 24 and 26). 4. Document according to one of claims 1 to 3, characterized α e - - 16 / - 209821/0925 indicates that the surface is covered with a layer (12) permeating visas. 5. Procedure for the manual coding of a document according to one of claims 1 to 4, characterized by crekennsteich net that the DokQftfl | Rt (lo) at predetermined points (16) is crebracht with a stamp (54) in contact, the two separated from each other by a border (64) has magnetically polarized areas (51, 52), namely W ~ with an angular position of this limit (64) corresponding to the respective data in relation to the broad side of the document. 6. The method according to claim 5, characterized in that the Dc ^v MT! Ent (lo) on the back with a sheet (5o) made of iron or soft steel is rear leat. 7. Stamp for coding a document according to one of claims 1 to 4, in particular according to the method according to claim 5 or 6, characterized by "inen spit" tapering permanent maonets (62), the one on the sides that are exposed is differently polarized and harvesting “ittlberll” on dtsMK Pole pieces (58, 6o) are applied to the sides, which are placed in marking areas (51, 52) on the pointed end (66) of this permanent magnet (62) ends, which can be placed on the document (lo) and which are marked by a narrow, the later border between the different polarized sections determining gap (64) are separated from each other. 209821/0925 8AD ORIGINAL