JP2003286694A - Identification medium - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a new identification medium producible in a low cost as compared to a conventional IC card, or the like, with reduced troubles insecurity points compared to magnetic cards. <P>SOLUTION: In this medium 1, the medium body 10 is constituted from a tissue paper sheet, a nonwoven fabric, a porous sheet of a plastic or a rubber, and a pore pattern as a checking parameter is formed by entanglement of fibers F constituting the tissue paper or nonwoven fabric in the case of the tissue paper or the nonwoven fabric. A person having the identification medium 1 or an article stuck with the identification medium can be identified by reading the pore pattern by using an optical reader, or the like, and checking because the pore pattern is spontaneously formed and should be only one specialized to the person. <P>COPYRIGHT: (C)2004,JPO

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an authentication medium for identifying a person or an article.

[0002]

2. Description of the Related Art An authentication system using an authentication medium such as an IC card or a magnetic card for identifying a person or an article by a machine, or a fingerprint or a voice in the case of a person, Authentication systems and the like that use physical characteristics such as the blood vessel pattern of the retina are becoming popular. However, the latter authentication system is suitable for identification of a limited number of users at a specific facility, for example, because the user needs to register his / her own characteristics in the machine in advance. It was not suitable for identifying an unspecified number of users or for identifying articles.

On the other hand, in the former authentication system using an authentication medium, the holder of the authentication medium is set to the data in the authentication medium or the data in the host computer derived from the data in the authentication medium. Can be identified based on. Therefore, it can be applied to identification for an unspecified number of users, such as insurance cards and securities, entrance / exit management for various facilities (admission tickets, etc.), transportation tickets, boarding tickets, etc. .

Further, for example, if the authentication medium is attached to the surface of the article as a label or attached to the article as a tag, the article can be identified by the authentication medium. Therefore, the authentication system using the authentication medium can be applied to the identification and management of articles in various physical distribution systems, for example. However, among the above-mentioned conventional authentication media, the IC card is a complicated card in which an IC chip in which identification information and the like are recorded and a terminal or an antenna for inputting / outputting data to / from this IC chip are incorporated in one card. Since it has a structure, there is a problem that the cost is extremely high.

Further, although the magnetic card has a simpler structure than the IC card and can be manufactured at a lower cost, it is easy to intentionally tamper with the recorded contents and there is a problem in terms of security. An object of the present invention is to solve the above-mentioned various problems of the conventional authentication medium, to provide a novel authentication medium which can be manufactured at extremely low cost and has few problems in terms of security.

[0006]

Means for Solving the Problem and Effect of the Invention The invention according to claim 1 is an authentication medium characterized by using a pore pattern of a sheet-like porous body as a matching element.
Examples of the sheet-shaped porous body include thin paper and non-woven fabric, and also a sheet of porous body made of plastic, rubber, or the like. Among them, in the former, a thin paper is made by filtering fibers. When manufacturing a non-woven fabric or a non-woven fabric, a pore pattern formed by entanglement of fibers, and in the latter case of a sheet of a porous body made of plastic or rubber, a pore pattern formed by foaming of a foaming agent, respectively. Used as a matching element. A sheet of porous rubber can be produced, for example, by mixing unvulcanized rubber with powder of salt or the like and vulcanizing it into a sheet, and then dissolving the salt powder from the sheet with water. ,
In that case, the pore pattern formed by elution of the powder is used as a matching element.

[0007] All of these pore patterns naturally occur in the process of producing a porous body, and there is no same one. Therefore, the pore patterns of individual authentication media are not the same. By reading the pattern with an optical reader or the like and collating the pattern, it is possible to identify a user who has the authentication medium, an article to which the authentication medium is attached, and the like. Moreover, the authentication medium may be formed entirely of the above-mentioned porous body, or a part thereof may be formed of the above-mentioned porous body as a matching element, and the structure is simple and can be manufactured at extremely low cost.

Since it is impossible to intentionally tamper with the pattern of the porous body, there is a security problem.
It can also be significantly improved over the past. As the porous body, it is preferable to use thin paper or non-woven fabric among the above materials because it is easy to reduce the thickness, is suitable for forming into the shape of an authentication medium such as a card, and is cheaper. Therefore, the invention according to claim 2 is the authentication medium according to claim 1, wherein a thin paper or a non-woven fabric is used as the porous body, and the pore pattern formed by the entanglement of the fibers forming the thin paper or the non-woven fabric is used as the matching element. is there.

When a part of the fibers constituting the thin paper or the non-woven fabric is colored, in addition to the identification by the pore pattern,
It is possible to identify the difference in the distribution pattern of the colored fibers, the difference in the color of the colored fibers, etc., and it is possible to increase the amount of information used for the identification. Therefore, the invention according to claim 3 is the authentication medium according to claim 2, wherein a part of the fiber is colored.

If the surface of the porous body is laminated with a transparent film, the durability of the pore pattern can be improved. Therefore, the invention according to claim 4 is the authentication medium according to claim 1, wherein a transparent film is laminated on the surface of the porous body.

[0011]

1 (a) is a plan view showing an example of an embodiment of an authentication medium 1 of the present invention. See also FIG.
(b) is an exploded perspective view illustrating a laminated structure of the authentication medium 1 of the above example. As shown in FIG. 1 (b), the authentication medium 1 of this example has a medium body 10 made of thin paper or non-woven fabric as a porous body, which is formed into a card shape similar to an IC card, a magnetic card or the like. It has a two-layer structure in which the transparent film 11 is laminated on one surface. By laminating the transparent film 11, the durability of the pore pattern can be improved as described above.

As shown in the enlarged view of FIG. 1 (a), the medium body 10 is made up of fibers F constituting the above-mentioned thin paper or nonwoven fabric.
Has a pore pattern used as a matching element, which is formed by the entanglement of. In the example of the drawing, a specific portion of the surface of the medium body 10 is surrounded by a printed frame 10a to define a reading area 10b having a pore pattern as a matching element. In this way, when the reading area 10b having a pore pattern is defined on the medium body 10, for example, reading with an optical reader or the like can be performed easily and reliably.

However, the reading area 10b may not be defined, and the entire surface of the medium body may be used as the reading area having a pore pattern. Further, the medium body 10 itself is formed of a plastic plate, cardboard, or the like, and the inside of the frame 10a of the medium body 10 is cut out, and thin paper or non-woven fabric is attached to the frame body 10a to form a pore pattern reading region 10b. Good.
The pore pattern in the reading area 10b surrounded by the frame 10a is
As mentioned earlier, it differs for each thin paper and non-woven fabric,
Since no one is the same, for example, when the authentication medium 1 is manufactured or issued, the pattern of the pore pattern in the reading area 10b is read by the above-mentioned optical reader or the like,
By associating the read pattern with various data and registering and managing them in the host computer, it is possible to identify a user who carries the authentication medium 1 or an article to which the authentication medium 1 is attached or attached. it can. Further, at the time of identification, the information registered in the host computer can be updated.

When a part of the fiber F constituting the thin paper or the non-woven fabric is colored, for example, as shown in FIGS. 2 (a) and 2 (b), the colored fiber F'in the reading area 10b. The position and the number are different for each thin paper and non-woven fabric, and there is no same one. Therefore, it is possible to identify by the difference in the distribution pattern of the colored fiber F ′, and the amount of information that can be used for identification is increased. Can be made. Furthermore, if the color of the fiber F'is made different, it is possible to make an identification based on the difference in the color, and it is possible to further increase the amount of information that can be used for identification.

On the surface of the medium body 10, for example, FIG.
As indicated by a chain double-dashed line in (b), a storage area 10c for printing or writing various information may be provided.
The thin paper constituting the medium body 10 of the authentication medium 1 is, for example, so-called Japanese paper made from natural fibers such as Kozo, Mitsumata, Manila hemp, jute hemp (burlap) and kenaf, rayon, vinylon, polyester, nylon. Examples thereof include paper made from chemical fibers (regenerated fiber and synthetic fiber) in the form of paper, or paper made by mixing natural fibers and chemical fibers into paper.

The thin paper is, for example, one kind of bast fiber such as jute hemp and kenaf, vein fiber such as manila hemp, or chemical fiber, or a mixture of two or more kinds at a predetermined ratio, lightly beaten, and wet paper. After adding an internal additive such as a force-enhancing agent, papermaking is performed by using a slanted braided paper machine or the like, and if necessary, a water-soluble resin is applied by an impregnation coating machine or the like to manufacture. Nonwoven fabrics include cotton, rayon, acetate,
Any sheet-shaped non-woven fabric made of various fibers such as nylon, polyester and polypropylene can be used.

The non-woven fabric is obtained by arranging one or more of the above fibers in a web (thin cotton) or mat shape by an appropriate method, and bonding the fibers with each other by the adhesive force of the adhesive or the heat fusion force of the fibers themselves. Manufactured by joining. It is preferable that the thin paper and the non-woven fabric have coarse mesh to some extent, as compared with those that are clogged. If the material is clogged, it tends to be difficult to confirm the pore pattern.

As the sheet-shaped porous body, a porous sheet made of plastic or rubber can be used as described above. Among these, examples of the plastic sheet made of a porous material include sheets made of various plastic foams such as polystyrene foam and polyvinyl chloride foam. These sheets are produced, for example, by mixing a plastic with a foaming agent and extruding and foaming into a sheet shape.

It is also possible to use urethane foam. A sheet made of urethane foam is produced by a conventional method in which polyester, water and diisocyanate are reacted with each other to cause crosslinking and foaming at the same time. As the porous sheet made of rubber, various porous sheets made of natural rubber or synthetic rubber such as acrylonitrile-butadiene copolymer rubber (NBR) can be used.

Such a porous sheet is produced, for example, by mixing unvulcanized rubber and a foaming agent that foams at a temperature not higher than the vulcanization temperature of the rubber, molding it into a sheet shape, and then foaming it simultaneously with vulcanization. To do. As mentioned above, it is water-soluble, such as salt,
And by mixing a powder of a compound that is not gasified at the vulcanization temperature of the rubber into an unvulcanized rubber, molding it into a sheet shape and vulcanizing it, and then washing it with water to elute the compound powder from the sheet. Can also be manufactured.

Any transparent film made of various materials can be used as the transparent film 11 for protecting the medium body 10 and preventing damage to the pore pattern due to scratches or the like. Examples of the transparent film 11 include polypropylene film, nylon film, polyester film, polyvinyl alcohol film, EV
Examples thereof include OH type films (ethylene / vinyl alcohol copolymer film, ethylene / vinyl acetate copolymer saponified film, etc.), polyvinylidene chloride type copolymer resin film and the like.

As a method for laminating the transparent film 11 on the surface of the medium body 10, various conventionally known laminating methods such as a wet laminating method, a dry laminating method, a solventless laminating method, a wax laminating method and a thermal laminating method are used. Are applicable.
An adhesive is used when laminating the transparent film 11 on the surface of the medium body 10 by these laminating methods. As the adhesive, any of various adhesives having adhesiveness to both can be used.

Examples of the adhesive include vinyl acetate type, acrylic type, vinyl chloride-vinyl acetate copolymer type,
Water-soluble type, emulsion type (above, for wet lamination), solvent type (for dry lamination), solvent-free, including various resins such as polyester, urethane, polyamide, etc., and according to the above-mentioned laminating method etc. Examples thereof include various types of adhesives such as type (for solventless laminating), hot melt type (for thermal laminating), ultraviolet curing type, and electron beam curing type.

Immediately after extrusion molding into a film by using an extrusion molding machine, the resin in the heat-melted state is transferred to the medium body 10.
The transparent film 11 can also be laminated on the surface of the medium body 10 by a so-called extrusion laminating method in which the transparent film 11 is formed by continuously laminating, adhering, cooling and solidifying on the surface of the medium. In this case, the adhesive can be omitted. In the figure, the transparent film 11 is laminated only on the surface of the medium body 10 on the upper surface side in the figure, but the transparent film 11 may be laminated on the lower surface, which is the opposite side.

The authentication medium 1 having a laminated structure of two layers or three layers transmits light for radiating light from one side thereof and reading the pattern of the silhouette of a pore pattern of the transmitted light transmitted to the other side. It can be used to identify a pore pattern by any of the formula and the reflection type in which light is irradiated from one side and the pattern of reflected light is read on the same side. In the case where the pore pattern is identified only by the reflection method, a colored film such as black that has a color tone that highlights the pore pattern may be laminated on the lower surface of the medium body 10 in the figure. Further, instead of the colored film, a sheet or a mount may be laminated.

For the above-mentioned printing or writing, a transparent film, a colored film, a sheet to be laminated on the surface of the transparent film 11 or on the opposite surface (not shown),
It may be performed on a portion corresponding to the area 10c, such as a mount. As described above, the authentication medium 1 in the above example is for insurance cards, securities (including credit cards, debit cards, cash cards, etc.) and entrance / exit management of various facilities (sports events, movie theaters, theaters, exhibitions). , Admission tickets for exhibitions, entrance / exit management at trade fairs, exhibitions, etc.), transportation tickets, boarding tickets, etc., and can be suitably applied to identification for an unspecified number of users.

Further, the authentication medium 1 is preferably applied to identification and management of articles in various physical distribution systems such as mail, courier and other transportation systems, warehouse management, inventory management in companies, book management in libraries and the like. You can also

[0028]

Example 1 As a sheet-shaped porous body which is a base of the medium body 10,
A long strip of non-woven fabric made of polypropylene fiber [Product name Eltas P3020 manufactured by Asahi Kasei Corporation, thickness 0.19 m
m, basis weight 11.5 g / m ² ]. As the transparent film 11, a long strip-shaped polyester film having a thickness of 200 μm was used.

The reading area 10b is provided on one side of the nonwoven fabric.
After continuously printing the frame 10a defining the above, a gravure roll is used, and an emulsion-type adhesive of vinyl chloride-vinyl acetate copolymer system is applied thereon with a coating amount of 1.0 g.
/ M ² was applied continuously. Then, the non-woven fabric immediately after coating and the transparent film 11 are continuously laminated by sandwiching the coated surface of the adhesive between a pair of laminating rolls, and then passed through a tunnel type drier and heated with 50 ° C. hot air. It was continuously dried to obtain a laminate having a two-layer structure.

Next, the obtained laminated body was cut into a card shape having a length of 54 mm and a width of 86 mm to manufacture an authentication medium 1. 100 authentication media 1 manufactured through the above steps
When the pattern of the pore pattern in the reading area 10b was read by an optical reader and compared, none of them completely matched. From this fact, the first embodiment
It has been confirmed that the authentication medium 1 of 1 can be used to identify a person or an article.

Example 2 Same as Example 1 except that a nonwoven fabric having the same physical properties as that used in Example 1 and mixed with 0.1% by weight of black colored fiber was used. Then, the authentication medium 1 was manufactured. 100 manufactured authentication media 1
When the pattern of the pore pattern in the reading area 10b was read by an optical reader and compared, none of them completely matched. The number and distribution of black colored fibers contained in the reading area 10b were also read by an optical reader and compared, and none of them completely matched.

From this, it was confirmed that the authentication medium 1 of the second embodiment can increase the amount of information used for identification as compared with the first embodiment. Example 3 A 25 μm-thick, black-colored PET film was attached to the surface of the authentication medium 1 having a two-layer structure manufactured in Example 1 on the side opposite to the transparent film 11 to form an authentication medium 1 having a three-layer structure. Manufactured.

The pattern of the fine pores in the reading area 10b of the 100 sheets of the authentication medium 1 manufactured was used as the transparent film 1
From the 1 side, when reading with an optical reader and comparing,
There was no perfect match. From this, it was confirmed that the pore pattern can be read even with the configuration of Example 3 and a person or an article can be identified.

[Brief description of drawings]

FIG. 1A is a plan view showing an example of an embodiment of an authentication medium of the present invention, and FIG. 1B is an exploded perspective view illustrating a laminated structure of the authentication medium of the above example. Is.

2 (a) and 2 (b) are distributions of the colored fibers in the reading area when a part of the fibers of the thin paper or the non-woven fabric forming the medium body of the authentication medium is colored. It is a top view explaining the state of.

[Explanation of symbols]

1 Authentication medium 10 Medium body (thin paper, non-woven fabric) 11 transparent film F fiber

Claims (4)

[Claims] 1. An authentication medium characterized by using a pore pattern of a sheet-shaped porous body as a matching element. 2. The authentication medium according to claim 1, wherein a thin paper or a non-woven fabric is used as the porous body, and a pore pattern formed by the entanglement of fibers constituting the thin paper or the non-woven fabric is used as a matching element. 3. The authentication medium according to claim 2, wherein a part of the fiber is colored. 4. The authentication medium according to claim 1, wherein a transparent film is laminated on the surface of the porous body.