JP3455260B2 - Magnetic recording media - Google Patents

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION The present invention relates to a magnetic card,
The present invention relates to a magnetic recording medium such as a magnetic commuter pass or a magnetic ticket, and particularly to a magnetic card provided with identification information by a magnetic bar code.

[0002]

2. Description of the Related Art Magnetic recording media such as various credit cards have sufficient safety against forgery and tampering because of their property value and high confidentiality. Is essential. In response to such a request, identification information is provided on each magnetic recording medium.

As one of means for giving this identification information, there is a method of forming a magnetic bar code on a magnetic recording medium. Usually, this magnetic barcode is created by the printing method,
A magnetic bar code in which a desired pattern is formed by magnetic ink containing magnetic powder and a dummy bar code formed in non-magnetic ink containing non-magnetic pigment are arbitrarily arranged as identification information. In order to read the magnetic bar code, a method is generally used in which an external magnetic field having an appropriate magnitude is applied, the magnetization of the magnetic bar code is detected by a magnetic sensor, and the change in magnetic resistance is detected.

However, when the residual magnetization of the magnetic bar code is large, the magnetic bar code must be degaussed after reading the magnetic bar code, and it is commonly used for visually observing the magnetization pattern of the magnetic tape. By magnetic developing method, for example, by sprinkling iron powder or contacting a commercially available magnetic viewer (manufactured by 3M Co.), the magnetization pattern of the magnetic barcode will be visually observed, so the contents of the magnetic barcode can be easily known. Therefore, the confidentiality of information cannot be maintained. Further, in order to demagnetize the magnetic bar code, it is necessary to provide a degaussing mechanism in the reading device, and there are disadvantages that the device becomes complicated and the size becomes large.

In order to improve such a problem, as described in Japanese Patent Application Laid-Open No. 1-109524,
Magnetic powders such as spherical carbonyl iron powders and gas atomized powders made of soft magnetic materials such as permalloy and sendust, which have a nearly spherical shape, have been used as the magnetic powders used in magnetic barcodes. Since these soft magnetic material powders have a small coercive force and a small residual magnetic flux density, they have a small residual magnetization when formed into a magnetic bar code. For this reason, it is not possible to visually check it with a magnetic viewer or the like, and since the content of the information of the magnetic barcode is not known, high safety can be secured.

[0006]

In the conventional magnetic recording medium as described above, since the magnetic powder made of the soft magnetic material contained in the magnetic bar code has a nearly spherical shape, the demagnetizing field is reduced. In general, the magnetic permeability is small even though it is a soft magnetic material because of its large coefficient. Therefore, when reading the magnetization pattern of the magnetic bar code by the magnetic head with a magnetic field of a practical level applied during the authenticity determination, a slight change in the magnetic field causes a large change in reproduction output, resulting in a decrease in reading accuracy.

In addition, since a general magnetic card is provided with a concealing layer and a protective layer on the magnetic bar code, the distance between the magnetic bar code and the magnetic head is large, and further, on the magnetic card. If dust adheres to the
The distance between the magnetic barcode and the magnetic head fluctuates. Further, in the normal usage of the magnetic card, reading is performed by a great variety of reading devices. In such a situation, the accuracy and reliability in reading the magnetization pattern of the magnetic bar code are unavoidably deteriorated due to variations in the gap between the magnetic head and the magnetic bar code and variations in the characteristics of the reader itself.

As a material having a small coercive force and a high magnetic permeability, there are needle-like or scale-like soft magnetic powders having an aspect ratio of about 40 or more. Such a material is easily saturated even in a weak magnetic field. Therefore, the fluctuation of the reproduction output due to the fluctuation of the applied magnetic field is small, but since the residual magnetization is large, the magnetization pattern of the magnetic bar code is easily recognized by means such as magnetic development, which is a drawback that safety cannot be ensured. is there.

The object of the present invention is to eliminate the above-mentioned drawbacks associated with the magnetic bar code provided in the magnetic recording medium such as the conventional magnetic card and to enable accurate reading under various conditions. The present invention provides a magnetic recording medium having a magnetic barcode.

[0010]

According to the present invention, in a magnetic recording medium provided with identification information consisting of a magnetic bar code, the magnetic bar code has an average aspect ratio of particles of 1.5 to 4 and a coercive force. The magnetic recording medium is characterized by containing flat particles made of sendust as a soft magnetic material having a magnetic field of 1200 A / m or less. Also,
According to the present invention, identification information consisting of a magnetic bar code is set.
In a single-digit magnetic recording medium, the magnetic bar code is
The average aspect ratio of the child is 1.5 to 4, and the coercive force is 1200.
Made of permalloy as a soft magnetic material with A / m or less
Magnetic recording medium containing flat particles
The body is provided.

That is, in the present invention, as the soft magnetic particles,
Flat particles with an average aspect ratio, expressed as the ratio of length to thickness, of 1.5 to 4 are used. A magnetic barcode using flat particles of a soft magnetic material having an aspect ratio in this specific range cannot be identified by observation by magnetic development, and even if the magnetic field applied during reading by a magnetic head fluctuates. The fluctuation of the reproduction output is very small, and both safety and stable reading performance can be achieved. Further, in the case of a powder having a coercive force of more than 1200 A / m, the residual magnetic flux density is large, and when a magnetic bar code is used, the remanent magnetization becomes large, and the magnetic bar code is identified by observation by magnetic development.

The average particle size of the flat particles of the soft magnetic material is 2
When large particles larger than 0 μm are used, many of the particles cannot pass through the screen during screen printing which is most commonly applied to form a magnetic bar code, and thus the plate The eyes may be clogged, the contour of the printed bar code or the smoothness of the surface may be deteriorated, and the variation in the shape of each magnetic bar code becomes large. Therefore, the read output of each magnetic bar code is not stable and is not practical.

[0013]

DESCRIPTION OF THE PREFERRED EMBODIMENTS A magnetic card according to an embodiment of the present invention will be described below with reference to the drawings.

The magnetic card 1 shown in FIG. 1 is made of a synthetic resin sheet such as polyethylene terephthalate, epoxy resin, polyvinyl chloride, or polycarbonate, or a base material made of synthetic paper or the like. A magnetic recording layer is provided by using a coating material containing the above, and a strip-shaped magnetic track 2 extending in the length direction of the magnetic card 1 is formed on the surface thereof. A magnetic bar code 3 is provided on the magnetic track 2.
The magnetic bar code 3 had a width of 1 mm, a length of 5 mm and a thickness of 20 μm. In the example of FIG. 1, the magnetic barcode 3 is configured by arranging a magnetic bar M containing a magnetic material and a dummy bar D containing no magnetic material in a predetermined order.

To form the magnetic bar M, an ink comprising vinyl chloride / vinyl acetate copolymer 25 parts by weight soft magnetic material 100 parts by weight solvent cyclohexanone 30 parts by weight butyl cellosolve 30 parts by weight isophorone 30 parts by weight was used. Printing by the printing method was applied.

The soft magnetic material used is flat particles having a sendust composition produced by the following method. The steps for producing the flat particles are shown below.

The molten alloy was poured into water and rapidly cooled to generate a large number of cracks in the steel ingot, and the cracks were pulverized in a dry vibration mill to obtain two particles of 9.5.
Using an attritor, Si-5.5Al-balance Fe alloy powder was added with a steel ball having a predetermined diameter and a predetermined weight relative to the powder, and 0.1% zinc stearate as a lubricant by weight. processed. Table 1 shows processing conditions and powder properties after processing.

With respect to the coercive force, a value of 1100 A / m or less was obtained for all the powders when heat-treated in hydrogen or nitrogen.

[0019]

[Table 1] For comparison, an ink prepared by using, as the soft magnetic material, flaky permalloy having an average particle size of 5 μm and an average aspect ratio of 50, and spherical carbonyl iron powder having an average particle size of 4 μm in the above composition was used. And then the width 1
A magnetic barcode having a size of 5 mm, a length of 5 mm, and a thickness of 20 μm was formed.

Table 2 shows the magnetic characteristics of each magnetic bar code.

[0021]

[Table 2] After adhering a Ba ferrite magnet to such a degree that the magnetic recording layer is not magnetized to these magnetic bar codes, the magnetic bar code was observed with a commercially available magnetic viewer. The magnetic flux of the magnetic bar code was not observed. Was about 20 mT or less. As shown in Table 2, the magnetic material sample No. contained in the magnetic bar code formed on the magnetic card of the present invention. 1, No. In No. 2, since the residual magnetic flux density is as small as 4.1 to 4.3 mT, even if the magnetic barcode formed on the magnetic card of the present invention is observed with a commercially available magnetic viewer, the magnetization pattern of the magnetic barcode is observed. It was impossible.

When a magnetic bar code is formed with scale-like permalloy, the residual magnetic flux density is as large as 40 mT, and after reading operation, it was observed with a commercially available magnetic viewer in a non-demagnetized state, and the magnetization of the magnetic bar code was found. A pattern was observed. Further, in the spherical carbonyl iron powder, the residual magnetic flux density was small as in the present invention, and it was impossible to observe the magnetic barcode with a commercially available magnetic viewer.

A magnetic card having a magnetic bar code is
Information can be read using a reader such as that shown in FIG. In FIG. 2, the DC bias current I _B
When a magnetic card is conveyed by applying a voltage, an output voltage (e ₀ ) corresponding to the magnetic bar code pattern is obtained. Here, if the distance between the magnetic card surface and the magnetic head is constant,
The strength of the DC bias current corresponds to the strength of the leakage magnetic field from the magnetic head. However, when reading with an actual magnetic head, dust, etc. adheres to the magnetic card,
Since the distance between the magnetic card surface and the magnetic head changes,
Even if the DC bias current is constant, the applied magnetic field applied to the magnetic barcode varies. In order to see the change in the reproduction output due to such a change in the applied magnetic field, the bias applied to the reading magnetic head in each of the magnetic particles formed of the flat particles of Sample 1, and the flaky permalloy and the spherical carbonyl iron powder of Comparative Example. current (I _B) to continue increasing from 0 to measure the changes in the relative output voltage (e ₀₎ at that time. Here, in order to avoid the influence of the concealing layer and the protective layer on the magnetic bar code, the measurement was performed with the magnetic bar code exposed on the magnetic card as shown in FIG. As the magnetic head, a combination head made of Sendust alloy having a head gap width of 40 μm and a reading track width of 1.5 mm was used, and the card transport speed was 1 m / sec.
The result is shown in FIG. 3, the horizontal axis represents the magnitude of the DC bias current (I _B), the vertical axis when the saturation value of the relative output voltage of the magnetic bar code using the magnetic material (e ₀₎ and 100% The relative output voltage (e ₀ ) is shown.
Note that when Sample 2 was used, almost the same results as Sample 1 were obtained.

[0024] Here, if the ,, Figure 3 and the DC bias current for reading a magnetic bar code in the magnetic head (I _B) is assumed to vary from 40mA to 20 mA, the scaly permalloy, to its saturation magnetic flux density 100%
98% of the saturation reproduction output from the size of the reproduction output of
Fluctuates to the playback output of. Similarly, the spherical carbonyl iron powder has a saturation magnetic flux density of 88 with respect to the spherical carbonyl iron powder.
The magnetic bar code using the flat particles of Sample 1 used in the magnetic card of the present invention varies from 94% of the reproduction output to 94% of the reproduction output of the sample 1. It changes to a reproduction output of 79%. The fluctuation range of the reproduction output is the largest at 25% for the magnetic barcode using the spherical carbonyl iron powder, 15% for the magnetic barcode of the present invention and 2% for the magnetic barcode using the flaky permalloy. The scale-like permalloy is the best in terms of the fluctuation of the reproduction output, but it has the drawback that a magnetic bar code is observed in a commercially available magnetic viewer as described above, and the fluctuation of the reproduction output is spherical spherical iron powder. Is big. In the magnetic bar code of the present invention, the fluctuation of the reproduction output is suppressed to be lower than that of the spherical carbonyl iron powder.

Further, spacers of various thicknesses are interposed between the magnetic head and the surface of three types of magnetic cards on which magnetic bar codes are formed by using inks containing the above-mentioned magnetic powders, respectively. The output was measured. In this case, since the DC bias current value is preferably slightly higher than the saturation current value, I _B = 30 mA based on the scale-like permalloy.
And The result is shown in FIG. In FIG. 4, the horizontal axis represents the gap (spacing) between the magnetic card surface and the magnetic head, and the vertical axis represents the relative reproduction output ratio (% when the reproduction output when the gap is 0 is 100%). ) Is shown.

As described above, during actual reading by the magnetic head, dust and the like adhere to the magnetic card, so that the gap from the surface of the magnetic card to the magnetic head fluctuates. If the gap between the magnetic card surface and the magnetic head is 0μ
From m (the state in which the magnetic card surface and the magnetic head are in close contact) to 10 μm due to adhesion of dust,
In FIG. 4, the reproduction output of the scale-like permalloy is reduced to 78% as compared with the reproduction output when the gap is 0 μm,
In the case of spherical carbonyl iron powder, the output is 52% lower than the reproduction output when the gap is 0 μm. Furthermore, the sample No. used for the magnetic card of the present invention. For the flat particles of No. 1, the reproduction output was reduced to 65% compared to the reproduction output when the gap was 0 μm.

Again, the fluctuation of the reproduction output with respect to the fluctuation of the gap from the surface of the magnetic card to the magnetic head is the smallest in the magnetic bar code using the flaky permalloy, but as described above, it is magnetic in the commercially available magnetic viewer. There is a drawback that a bar code is observed, and a magnetic bar code using spherical carbonyl iron powder has a large fluctuation in reproduction output. In the magnetic bar code of the present invention, the fluctuation of the reproduction output is
It is smaller than the magnetic bar code of spherical carbonyl iron powder.

As is clear from the above description, the magnetic bar code using the flaky soft magnetic material having a large aspect ratio has a small fluctuation in the reproduction output due to the fluctuation of the applied magnetic field, but it is a commercially available magnetic viewer. The magnetic bar code is observed in the above, and the magnetic bar code using the spherical soft magnetic material cannot be observed with a commercially available magnetic viewer, but the fluctuation of the reproduction output due to the fluctuation of the applied magnetic field is large. I understand.

On the other hand, a magnetic bar using flat particles made of a soft magnetic material having an average aspect ratio of particles of 1.5 to 4 and a coercive force of 1200 A / m or less formed on the magnetic card of the present invention. In the code, commercially available magnetic
The magnetic bar code is not observed in the viewer, the fluctuation of the reproduction output due to the fluctuation of the applied magnetic field is suppressed to a small level, and the stable reading by the magnetic head becomes possible.

[0030]

As described above, according to the present invention, the magnetic bar code provided as identification information on the magnetic recording medium has an average aspect ratio of particles of 1.5 to 4 and a coercive force of 1200.
It contains flat particles made of a soft magnetic material having an A / m or less. Since this magnetic bar code has a small residual magnetization, it cannot be visually recognized by a magnetic viewer, and high security against forgery or tampering is secured. Further, in the state where a predetermined magnetic field is applied, the fluctuation of the reproduction output during reading of the magnetic head is suppressed to a small level, and stable reading is possible.

[Brief description of drawings]

FIG. 1 is a plan view of a magnetic card according to an embodiment of the present invention.

FIG. 2 is an explanatory diagram showing a relationship between a magnetic head and an output current (e ₀ ) when reading a magnetic barcode provided on a magnetic card.

FIG. 3 is a graph showing a relationship between a DC bias current and a reproduction output voltage of a magnetic bar code formed by using the flat particles used in the present invention, a conventional spherical carbonyl iron powder and a flaky permalloy, respectively.

FIG. 4 is a graph showing the effect of spacers on the magnetic bar code composed of the flat particles used in the present invention, the conventional spherical carbonyl iron powder and the flaky permalloy.

[Explanation of symbols]

1 magnetic card Two tracks 3 magnetic barcode M magnetic bar D dummy bar

─────────────────────────────────────────────────── ─── Continuation of front page (58) Fields surveyed (Int.Cl. ⁷ , DB name) G06K 19/06

Claims (2)

(57) [Claims] 1. A magnetic recording medium provided with identification information comprising a magnetic bar code, wherein the magnetic bar code has an average particle aspect ratio of 1.5 to 4 and a coercive force of 1200 A.
A magnetic recording medium containing flat particles made of sendust as a soft magnetic material having a density of not more than / m. 2. An identification information comprising a magnetic bar code is provided.
In the magnetic recording medium, the magnetic bar code is
Has an average aspect ratio of 1.5 to 4 and a coercive force of 1200 A
/ M or less is made of permalloy as a soft magnetic material
Magnetic recording medium containing flat particles
body.