JPH07309090A - Security card and its reading device - Google Patents

Abstract

(57) [Abstract] [Purpose] To provide a security card that is difficult to forge and falsify and a reading device for the security card. [Structure] A reversible thermosensitive layer 3 which is located above the card substrate 1 and repeats coloring and erasing due to temperature change, and an infrared reflecting layer 5 which is located below the card substrate 1 and has infrared reflectivity, It has a card base material 1 and a background layer 2 provided between the reversible heat-sensitive layer 3 and a lower surface of the infrared reflection layer 5,
A barcode-like identification code 6 having infrared absorption is formed and configured.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a security card and its reader, and more particularly to a security card such as an ID card and a prepaid card which requires authenticity determination and its reader.

[0002]

2. Description of the Related Art Various types of I that are commonly used at present
D cards, prepaid cards, and the like are provided with various security functions in order to prevent unauthorized use due to forgery, falsification, and the like. For example, in a magnetic card, forgery or tampering is provided by providing magnetic data for authenticity determination separately from the information recording section, or by providing a part of the card with an invisible identification code that can be detected only by infrared rays, such as a bar code. Unauthorized use due to such reasons is prevented.

[0003]

However, in the conventional magnetic card of this type, a person having appropriate knowledge can falsify the magnetic data by using a commercially available product or a modified magnetic card reader / writer or the like. It is possible to do so. Further, the invisible identification code by infrared rays has a drawback that it cannot be forged if the position and pattern of the code on the card are clarified.

An object of the present invention is to solve the above-mentioned drawbacks of the prior art and to provide a security card which is difficult to forge or falsify and a reading device for the security card.

[0005]

According to the present invention, a reversible heat-sensitive layer located on one surface side of a card substrate and repeating coloring and decoloring due to temperature change, and the other surface of the card substrate. Located on the side, an infrared reflective layer having infrared reflectivity,
The card base material and the background layer provided between the reversible heat-sensitive layer are provided, and an identification code having an infrared absorbing property is formed on the opposite side of the infrared reflective layer from the card base material side. A security card characterized in that it is obtained.

Further, according to the present invention, infrared rays are radiated from the surface on which the identification code is formed, and a region corresponding to the identification code in the reversible thermosensitive layer forming region is defined. By raising the temperature to a temperature, a security card is obtained in which a virtual identification code corresponding to the identification code is generated in the formation area of the reversible thermosensitive layer.

Further, according to the present invention, in the security card reader, first heating means for irradiating the identification code with infrared rays and heating the identification code formation surface from the infrared reflection layer side. And an identification code reading unit that reads the pattern of the virtual identification code generated by the heating, and the entire area where the reversible thermosensitive layer is formed after the pattern of the virtual identification code is read by the identification code reading unit. Second heating means for heating from the side of the reversible heat-sensitive layer, confirmation means for confirming the presence or absence of the virtual identification code after heating by the second heating means, and receiving read data from the identification code reading means , Determining whether or not the pattern of the virtual identification code is present, determining whether or not the pattern of the virtual identification code is a predetermined pattern, and Receiving over data, said virtual identification code reader of the security card, characterized in that is comprises a discriminating means for discriminating whether it is erased can be obtained.

[0008]

In the security card according to the present invention, when the surface having the identification code formed of the infrared absorbing material is irradiated with the infrared rays, the identification code absorbs the infrared rays and generates heat. The heat generated is generated by the card substrate (generally 0.15
The resin film having a thickness of ˜0.25 mm reaches the back surface, that is, the reversible thermosensitive layer, and the area corresponding to the identification code in the reversible thermosensitive layer forming area is colored or erased according to the heated temperature. To color. As a result, the pattern corresponding to the identification code is reproduced on the reversible thermosensitive layer. Therefore, since the identification code cannot be reproduced unless the infrared absorption capacity of the identification code, the thermal conductivity of the card base material, and the temperature characteristics of coloring / decoloring of the reversible thermosensitive layer are the same as those of the regular card, forgery is difficult. is there.

Further, in the security card according to the present invention, by arranging the band-shaped members of the identification code so as to have different infrared absorption abilities, the identification code of the identification code can be obtained in relation to the coloring / decoloring temperature of the reversible thermosensitive recording layer. Each band member is colored,
Since a state such as decoloring or no change is exhibited, it is possible to set a complicated identification code pattern by appropriately combining these and to enhance the security effect.

Further, in the security card reader according to the present invention, the identification code is reproduced on the reversible thermosensitive layer by heating the identification code forming surface by infrared irradiation, and after the reproduced identification code is read, the reversible thermosensitive layer is read. The identification code part reproduced in the layer is heated uniformly over the entire surface of the reversible thermosensitive layer so that the identification code part becomes invisible, so that the identification code is colored or decolored, and the identification code information and Only when both of the coloring and erasing mechanisms are as set, the card is determined to be "true". Therefore, even if a card other than the card having the structure according to the present invention is forged, the card is not determined to be "true" and the forgery can be prevented.

[0011]

Embodiments of the present invention will be described below with reference to the drawings.

FIG. 1 is a sectional view showing the structure of a security card according to the present invention. In FIG. 1, a security card according to the present invention includes a card substrate 1 and a card substrate 1.
Background layer 2 formed on the upper surface of the reversible thermosensitive layer 3, the reversible thermosensitive layer 3 formed on the upper surface of the background layer 2, the protective layer 4 formed on the upper surface of the reversible thermosensitive layer 3, and the card substrate 1. The infrared reflective layer 5 is formed on the lower surface of the infrared reflective layer 5, and the identification code 6 made of the infrared absorbing material is formed on the lower surface of the infrared reflective layer 5.

The card substrate 1 is made of a polymer film,
For general use, polyethylene, polypropylene, polyester, vinyl chloride or the like is suitable. Further, paper, metal, glass, ceramics or the like may be used if various conditions required for the card such as durability, water resistance and chemical resistance are satisfied. However, the identification code 6
When it is necessary to increase the resolution of the identification code reproduced by the reversible thermosensitive layer 3, such as when the identification code 6 is small or the interval between the strip codes of the identification code 6 is narrow, a material having good heat conduction is selected. Better.

The background layer 3 is provided to provide the contrast necessary for detecting the identification code reproduced by the color development or the color erasing of the reversible thermosensitive layer 4. The material of the background layer 3 is a dark-colored paint such as a black color whose light reflectance is lower than that of the reversible thermosensitive layer 4 or a silver color having a high light reflectance (lower than that of the reversible thermosensitive layer 4). A paint or a metal deposition thin film such as aluminum is used.

Various thermochromic materials are suitable for the reversible thermosensitive layer 4. In addition, a reversible thermosensitive recording material in which an organic low molecular weight material such as a higher fatty acid is dispersed in a resin matrix such as vinyl chloride or a copolymer thereof (JP-A-58-1).
No. 91190 and Japanese Patent Application Laid-Open No. 60-193,691), in which the transparency reversibly changes with temperature and the state can be maintained semipermanently at room temperature, and in addition, It has the feature that the temperature of coloring and erasing can be freely set according to the type and composition ratio.

The protective layer 4 is provided on the upper surface of the reversible thermosensitive layer 3, and its material is required to have transparency, heat resistance, abrasion resistance and the like. Therefore, it is preferable to use an ultraviolet-curable coating varnish containing wax, silicon, or a fluororesin, for example. As an example, Dicure New ZO
P varnish (manufactured by Dainippon Ink and Chemicals, Inc.) may be formed in a thickness of 1 to 3 μm by means such as offset printing. In addition, SiO ₂ and A
It may be formed by coating a thin film of an inorganic material such as l ₂ O ₃ by a film forming method such as sputtering.

The infrared reflecting layer 5 is provided to prevent the portions other than the identification code 6 from being heated by infrared rays. There is no particular need as long as it is a white polymer film which is a general card base material, but heating energy, infrared absorption capacity of identification code 6, code pattern, card base material thickness and heat conduction, reversible thermosensitive material Depending on various conditions such as the coloring and decoloring temperature of the above, an identification code (hereinafter, virtual code) reproduced on the reversible thermosensitive layer 3 may be obtained by using a light-colored paint such as white or a metal deposition thin film such as aluminum. Sometimes called "identification code" can be effectively reproduced.

The identification code 6 is preferably a material having a high infrared absorption ability. Therefore, a general black ink having carbon black as a pigment may be formed by various printing methods. In the structure of the identification code 6, since the position and the pattern can be easily discriminated only by the black ink, the infrared transmissive black ink which does not contain carbon black and which is a mixture of the three primary colors of red, yellow and blue is identified as the concealing layer. A higher forgery prevention effect can be obtained by concealing so as to cover the area other than the area where the identification code 6 is formed in the area where the code 6 and the infrared reflective layer 5 are formed.

There is also an infrared absorbing material which is almost transparent in the visible light range. As an example, the infrared absorbing agent IRF-1000 (manufactured by Fuji Photo Film Co., Ltd.) is dispersed in a transparent resin material in an amount of 2 to 5% by weight, and the resultant is used as a screen. The identification code 6 can be formed by performing printing or gravure printing.

When a pattern or the like is printed on the side where the identification code 6 is formed, it is necessary to take care so that a black pattern is not applied to the area where the identification code 6 is formed. This is because the black pattern absorbs infrared rays, so that it cannot be distinguished from the identification code 6, and the pattern of the virtual identification code corresponding to the identification code 6 does not occur in the reversible thermosensitive layer 3. Therefore,
If this is unavoidable, the above infrared-transparent black ink may be used.

If the infrared energy applied to the identification code 6 is constant, the temperature at which the reversible thermosensitive layer 3 develops color by arranging the infrared absorption capabilities of the identification code 6 differently (hereinafter referred to as the color development temperature). And the temperature at which the color of the reversible thermosensitive layer 3 is erased (hereinafter referred to as the color erasing temperature), the identification code part exhibits a state such as color development, color erasure, or no change. Therefore, these are appropriately combined. By doing so, the security effect can be enhanced. That is, if the infrared absorbing ability is changed for each strip-shaped member having the identification code 6, the infrared absorbing ability is high, that is, the infrared ray is absorbed as much as possible to raise the temperature to the temperature required to generate and decolor the reversible thermosensitive layer 3. Since the virtual identification code is reproduced only in the region corresponding to the band-shaped member having the infrared absorbing ability, the pattern setting of the virtual identification layer can be increased without changing the pattern of the identification code 6.
In order to make the infrared absorbing ability of the identification code 6 different, the infrared absorbing material may be appropriately mixed with the infrared transmitting material having the same color tone.

FIG. 2 is a diagram showing the configuration of a reading device used in the security card according to the embodiment of the present invention. The arrow in the figure indicates the moving direction of the security card. In the figure, the upper side of the security card 7 is the reversible thermosensitive layer 3 side, and the lower side is the identification code 6 side.

The security card reader according to the present invention comprises a card carrying roller 8, an infrared lamp 9 as a first heating means, an identification code reading section 10 as an identification code reading means, and a second heating means. A heat sensitive layer heating element 13 as a reference, an identification code reading section 11 as a confirmation means,
An identification code judging section 12 as a judging means is provided.

When the security card 7 is inserted into the reading device, it is first conveyed by the card conveying roller 8. The infrared lamp 9 irradiates the identification code 6 with infrared rays from below to heat the surface on which the identification code 6 is formed. This heating causes the identification code 6 to generate heat, and the heat is transmitted through the infrared reflective layer 5, the card base material 1, and the background layer 2, and the reversible thermosensitive layer 3 is formed.
Reach In the area where the reversible thermosensitive layer 3 is formed, a pattern (virtual identification code) of the identification code 6 in which the width of each strip-shaped member and the interval between each strip-shaped member are the same is reproduced. Identification code reading unit 10
Reads the pattern of the virtual identification code generated by this heating. After the pattern of the virtual identification code is read by the identification code reading unit 10, the thermosensitive layer heating element 13 heats the entire area where the reversible thermosensitive layer 3 is formed from above.
The entire surface of the reversible thermosensitive layer 3 is colored or erased, and the pattern of the virtual identification code is erased.

After heating by the heat sensitive layer heating element 13, the presence or absence of the virtual identification code is confirmed by the identification code reading section 11. The identification code determination unit 12 receives the read data from the identification code reading unit 10 to determine the presence or absence of the pattern of the virtual identification code, and the pattern of the virtual identification code is a preset pattern. Or not. Further, it receives the read data from the identification code reading unit 11 and determines whether or not the virtual identification code is erased. Here, when the pattern of the virtual identification code read by the identification code reading unit 10 matches the set pattern, and the erased state of the virtual identification code thereafter is as set, the determination unit 12 sets the card to " It is determined to be “true”, that is, a “genuine card”.

Before the use of the security card according to the present invention, when the entire reversible thermosensitive layer is in the colored state and the decolored state, the reversible thermosensitive layer 3 can be repeatedly heated by heating the infrared lamp 9 and the thermosensitive layer heating element 13. It is different whether to raise. Hereinafter, the case in which the entire reversible thermosensitive layer before use is in the color-developed state and the case in which it is in the decolored state will be described in detail separately.

When the entire reversible thermosensitive material used in the reversible thermosensitive layer 3 is in a color-developed state before use, heat is applied to the reversible thermosensitive material so that the temperature of the reversible thermosensitive material becomes When the temperature rises to 1 (erasing temperature) and then falls to room temperature, the state of decoloring occurs. Further, when heat is applied to the reversible heat-sensitive material, the temperature of the reversible heat-sensitive material rises to a second temperature (coloring temperature) higher than the first temperature, and then falls to room temperature, resulting in a colored state. . still,
In this case, the first temperature and the second temperature differ depending on the type of the reversible thermosensitive material.

On the other hand, when the entire reversible thermosensitive material used in the reversible thermosensitive layer 3 is in a decolored state before use, heat is applied to the reversible thermosensitive material, and the temperature of the reversible thermosensitive material is increased. Rises to a first temperature (coloring temperature) to be in a colored state, and then maintains that state even if the temperature drops to room temperature.
Furthermore, when heat is applied to the reversible thermosensitive material, the temperature of the reversible thermosensitive material rises to a second temperature (decoloring temperature) lower than the first temperature, and then falls to room temperature. become.

As specific examples of the temperature characteristics of the above-mentioned coloring temperature and erasing temperature, for example, in the case of the above-mentioned thermochromic material, the coloring temperature is 105 ° C to 120 ° C and the erasing temperature is 70 ° C to 95 ° C. Is. Even in this case, the temperature characteristics are changed by changing the composition ratio of the thermochromic material.

In the above description, the color-developed state and the color-erased state are referred to. Specifically, the color-erased state means a colorless and transparent state, and the color-developed state changes the transparency and becomes cloudy. State. Therefore, the change in the coloring state or the erasing state means that the reversible thermosensitive layer 3 itself changes the light reflectance and accordingly the transparency changes. Therefore, the actual virtual identification pattern is, for example, When the color of the background layer 2 which is the base is red,
When the reversible thermosensitive layer 3 is in the decolored state, it is recognized as red from the upper side of the reversible thermosensitive layer 3, and when the reversible thermosensitive layer 3 is in the colored state, it is recognized as pink from the upper side of the reversible thermosensitive layer 3. To be done.

The operation of the reading device in each of the above cases will be described below. When the entire reversible thermosensitive material used for the reversible thermosensitive layer 3 is in a colored state before use, the infrared lamp 9 raises the temperature of the reversible thermosensitive material to a first temperature (decoloring temperature). The identification code 6 is heated so as to cause it. After that, when the temperature is lowered to room temperature, a region corresponding to the identification code in the formation region of the reversible thermosensitive layer 3 is in a decolored state to form a virtual identification code pattern. After that, the identification code reading unit 10 reads the pattern of the virtual identification code generated by heating. After the pattern of the virtual identification code is read by the identification code reading unit 10, the thermosensitive layer heating element 13 sets the temperature of the reversible thermosensitive material to the second temperature (coloring temperature) higher than the first temperature.
When the entire surface of the reversible thermosensitive layer 3 is heated so as to rise, and then the temperature is lowered to room temperature, the entire reversible thermosensitive layer 3 is in a colored state and the pattern of the virtual identification code is erased. After that, the identification code determination unit 12 determines, but the specific operation is as described above.

When the entire reversible thermosensitive material used in the reversible thermosensitive layer 3 is in a decolored state before use, the infrared lamp 9 changes the temperature of the reversible thermosensitive material to a first temperature (coloring temperature). When the temperature of the identification code 6 is lowered to room temperature, the area corresponding to the identification code in the area where the reversible thermosensitive layer 3 is formed becomes a colored state and the pattern of the virtual identification code is generated. To form. After that, the state is maintained. The identification code reading unit 10 reads the pattern of the virtual identification code generated by heating. After the pattern of the virtual identification code is read by the identification code reading unit 10, the thermosensitive layer heating element 13 raises the temperature of the reversible thermosensitive material to a second temperature (erasing temperature) lower than the first temperature. When the entire surface of the reversible thermosensitive layer 3 is heated so that the temperature of the reversible thermosensitive layer 3 is lowered to room temperature, the entire reversible thermosensitive layer 3 is in a decolored state, and the pattern of the virtual identification code is erased. After that, the identification code determination unit 12 determines, but the specific operation is as described above.

In the above-mentioned embodiment, each material constituting the security card varies depending on required characteristics, and the combination thereof is determined by a concrete experiment. Further, since similar effects can be obtained if the properties are similar, the present invention is not limited to the embodiments and can be variously modified and carried out.

As described above, according to the security card reader of the present invention, the identification code 6 can be read by a special method, and even if the identification code is provided on the lower surface of the card, the identification code 6 is actually used. Since the virtual identification code is read to verify the authenticity of the card, such fraud can be easily prevented.

Even if such a structure is known,
Subtly changing the composition of the reversible heat-sensitive material, setting a number of patterns of temperature characteristics of coloring / decoloring, individually changing the infrared absorption ability of each strip-shaped member of the identification code 6 and setting a large number of virtual identification code patterns. Therefore, it is not easy to manufacture a counterfeit card having such a pattern.

[0036]

According to the present invention, a reversible heat-sensitive layer is provided on one surface of a card base material, and an identification code made of an infrared absorbing material is provided on the other surface thereof to provide a security card which is difficult to forge or falsify. it can.

Further, according to the present invention, it is possible to provide a high security card which is more difficult to forge or falsify by changing the infrared absorbing ability of each identification code and combining them appropriately.

Further, according to the present invention, it is possible to provide a security card reading device for surely identifying a forged or falsified card.

[Brief description of drawings]

FIG. 1 is a sectional view showing a configuration of a security card according to the present invention.

FIG. 2 is a diagram showing a configuration of a security card reader according to the present invention.

[Explanation of Codes] 1 Card Base Material 2 Background Layer 3 Reversible Heat Sensitive Layer 4 Protective Layer 5 Infrared Reflective Layer 6 Identification Code 7 Security Card 8 Card Conveying Roller 9 Infrared Lamp 10, 11 Identification Code Reading Section 12 Identification Code Determination Section 13 Heat sensitive layer heating element

─────────────────────────────────────────────────── ─── Continuation of the front page (51) Int.Cl. ⁶ Identification code Internal reference number FI technical display location B41M 5/36 G06K 7/12 Z 9069-5L 19/06

Claims (8)

[Claims] 1. A reversible thermosensitive layer located on one surface side of a card base material, which repeats coloring and decoloring according to temperature change, and an infrared reflectiveness located on the other surface side of the card base material. It has an infrared reflection layer and a background layer provided between the card base material and the reversible heat-sensitive layer, and has an infrared absorbing property on the side opposite to the card base side of the infrared reflection layer. A security card having an identification code formed thereon. 2. The security card according to claim 1, wherein infrared rays are radiated from a surface on which the identification code is formed, and an area corresponding to the identification code is formed in an area where the reversible thermosensitive layer is formed. The security card is characterized in that a virtual identification code corresponding to the identification code is generated in the formation area of the reversible thermosensitive layer by raising the temperature to a predetermined temperature. 3. The security card according to claim 2, wherein the background layer has a light reflectance different from that of the virtual identification code. 4. The security card according to claim 1, wherein each band-shaped member forming the identification code has a different infrared absorption performance. 5. The security card according to claim 1, wherein the identification code forming area is covered,
A security card, wherein a concealing layer is printed so as to cover an area other than the area where the identification code is formed in a layer located on the side opposite to the card base material side of the infrared reflective layer. 6. The security card reader according to claim 2, further comprising: a first heating unit that irradiates the identification code with infrared rays and heats a surface on which the identification code is formed from the infrared reflective layer side. Identification code reading means for reading the pattern of the virtual identification code generated by the heating;
Second heating means for heating the entire reversible thermosensitive layer formation region from the reversible thermosensitive layer side after the pattern of the virtual identification code is read by the identification code reading means,
After heating by the second heating means, confirmation means for confirming the presence / absence of the virtual identification code, and read data from the identification code reading means to determine the presence / absence of the pattern of the virtual identification code, and And a determination unit that determines whether or not the pattern of the virtual identification code is a predetermined pattern, receives the data from the confirmation unit, and determines whether or not the virtual identification code is erased. A security card reading device characterized in that 7. The security card reader according to claim 6, wherein when the entire reversible thermosensitive layer is in a color-developed state before the use of the security card, the first heating means includes the reversible thermosensitive layer. Of the formation area of the identification code, the area corresponding to the identification code is heated to a first temperature to make the area corresponding to the identification code in a decolored state, and the second heating unit causes the reversible feeling. A device for reading a security card, characterized in that the reversible thermosensitive layer as a whole is brought into a colored state by heating until the temperature of the formation region of the thermal layer reaches a second temperature higher than the first temperature. 8. The security card reading device according to claim 6, wherein when the entire reversible thermosensitive layer is in a decolored state before the security card is used, the first heating means is the reversible thermosensitive layer. Of the layer formation regions, the region corresponding to the identification code is heated until the temperature reaches a first temperature to bring the region corresponding to the identification code into a color-developed state, and the second heating unit causes the reversible sense. A device for reading a security card, wherein the reversible thermosensitive layer as a whole is decolored by heating until the temperature of the region where the thermal layer is formed reaches a second temperature lower than the first temperature.