JP4629485B2 - Book with non-contact IC tag - Google Patents

Description

  The present invention relates to a book with a non-contact IC tag. Specifically, in a book having a metal vapor deposition layer on the front cover, back cover, cover cover or binding paper and having a non-contact IC tag inside, the metal vapor deposition layer has a sea / island structure and the vapor deposition surface is The present invention relates to a book with an insulating non-contact IC tag.

Non-contact IC tags can be used to record and hold information and exchange information by communicating with external devices in a non-contact manner.
The same applies to publications such as books and magazines. In addition to the effects of inventory management, return management and shoplifting prevention, it can also be used for lending processing in libraries, so contactless IC tags should be fully introduced at an early stage. Is required.

  One problem with attaching non-contact IC tags to books such as books and magazines is that when a pattern containing a metal vapor deposition layer is used on the cover, back cover, cover cover or binding paper of the book, the metal vapor deposition layer Since it has conductivity, there is a problem of hindering communication between a non-contact IC tag and a reader / writer inside a book, a magazine, or the like. The same applies when a bound advertisement sheet having a metal vapor deposition layer is inserted into the booklet. This is a problem that occurs even when the non-contact type IC tag is mounted on an object made of a metal material or a metal container. The cause of the communication hindrance is that an eddy current is generated in the metal deposition layer due to an alternating magnetic field generated by electromagnetic waves for non-contact IC tag transmission / reception, and this eddy current generates a magnetic flux repelling the transmission / reception magnetic flux, thereby transmitting / receiving It is considered that the magnetic flux for use is attenuated and transmission / reception becomes difficult. When the deposited layer has a narrow area such as letters or fine lines, it does not become an obstacle, but when the deposited layer has a large area, the obstacle becomes remarkable.

Although books such as books and magazines with metal-deposited layers among a large number of publications are limited at present, the reliability of the entire non-contact IC tag management system should be read even if some of them are defective. Decreases. Moreover, since such metal vapor deposition has a metallic luster that cannot be expressed by printing, it is considered that the tendency to be employed will increase in the future.
If some "books" cannot be contacted, there is a problem that the usefulness of the entire system is reduced, and data is lost or mistaken and reliability is lost. It is clear that it cannot be handled except for “books” with metal-deposited patterns.

Therefore, there is a demand for a measure that does not hinder communication between the non-contact IC tag and the reader / writer while using the metal vapor-deposited pattern. By the way, the prior art which utilized the sea and island structure for metal vapor deposition conventionally exists like patent document 1-patent document 4. The sea / island structure (also referred to as island structure, island shape, or island shape) is a vapor deposition method using vapor deposition metal as a small island, and it is known that the vapor deposition surface is insulative. However, none of these prior documents proposes to use a sea-island structure deposition layer for a non-contact IC tag.
Note that there are Non-Patent Document 1, Non-Patent Document 2, and the like as technical books describing generation of sea / island structures and the like.

JP-A-62-174189 JP-A 63-157858 JP 63-249688 A JP-A-4-141497 "Thin Film Engineering Handbook" (Ohm) edited by Japan Society for the Promotion of Science Thin Film No. 131 Committee (published in 1972) Chapter 1 Vacuum Deposition (I-93 to I-95) “Thin Film” (Baifukan) [Sadafumi Yoshida] Published June 1990 Chapter 1 Vacuum Deposition (Pages 14-16)

  Therefore, the present invention makes it possible to use a non-contact IC tag while ensuring a beautiful pattern with metal vapor deposition on books such as books and magazines. As a result of intensive research, the present invention has been completed.

The gist of the present invention that solves the above problems is that the front cover, the back cover, the cover cover, or the binding paper has a pattern including a metal vapor deposition layer, and the book has a non-contact IC tag inside the book. a sea-island structure have a insulative, the sea-island structure of the metal deposition layer, a vapor deposition layer formed on the substrate film of the transfer foil sea islands structured by photo-etching, the sea-island structure A book with a non-contact IC tag , wherein the deposited layer is transferred to a front cover, a back cover, a cover cover, or a binding sheet .

In the book with a non-contact IC tag, the metal deposition layer is made of aluminum (Al), silver (Ag), tin (Sn), zinc (Zn), tin-aluminum (Sn-Al) alloy, tin-silicon (Sn-Si). ) It can be a deposited layer of alloy.

  Further, if the sea / island structure of the metal vapor deposition layer is such that the island size is 20 nm to 1 μm and the distance between the islands is 10 nm to 500 nm, an appropriate insulating layer is formed.

In the book with a non-contact IC tag of the present invention, the non-contact IC tag can be used without any communication obstruction while using a beautiful design using metal vapor deposition on the front cover, back cover, cover cover, binding paper, etc. The reliability of the management system using IC tags can be increased.
In the book with a non-contact IC tag according to the present invention, by adopting a non-contact IC tag management system, it is possible to eliminate design restrictions that limit metal deposition of books and magazines.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. FIG. 1 is a view showing a book with a non-contact IC tag according to the present invention, and FIG. 2 is a view for explaining a sea / island structure.

  As shown in FIG. 1, the book 1 with a non-contact IC tag according to the present invention has a non-contact IC tag 2 mounted inside the cover 11 of the book 1. However, the mounting position of the non-contact IC tag 2 is not limited to the portion where the cover is widened, and may be the inner surface of the back cover, or may be mounted on the back portion. As is well known, communication is possible even inside a book if there is no metal body or metal film that prevents communication between the non-contact IC tag 2 and the external reader / writer.

The book 1 with a non-contact IC tag according to the present invention is characterized in that the front cover, the back cover, the cover cover, or the binding paper has a pattern including the metal vapor deposition layer 4. The cover cover (not shown) is configured to cover and protect the entire front cover and back cover with a covering that protects the entire outer surface of the book 1.
Therefore, the pattern including the metal vapor deposition layer 4 may be on the cover cover, and may be on both the cover cover and the front cover, the back cover, or the binding paper. Normally, when such a pattern including the metal vapor deposition layer 4 exists between the non-contact IC tag 2 and the external reader / writer 5, the metal vapor deposition layer 4 is a thin layer but is a metal film, so that radio waves for reading are transmitted. It is known that communication is impossible due to shielding.

FIG. 2 is a diagram illustrating the sea / island structure. FIG. 2A shows a conventionally known sea / island structure that can be formed by selecting a vapor deposition material, vapor deposition conditions, and the like. The metal vapor deposition layer 4 is formed with a vapor deposition layer comprising minute islands 4a and gaps 4b between the islands. The sea / island structure as shown in FIG. 2A can be formed by directly depositing on the cover, cover paper, etc., or once deposited on the transfer film and then transferred to the cover, cover paper, etc. . In any case, since the deposited layer is formed by direct deposition, the island shape and the like are indefinite and non-uniform.
The average island size of such islands 4a is preferably 20 nm to 1 μm, and the average of the inter-island gaps 4b is preferably about 10 nm to 500 nm. If the island size is smaller than 20 nm, the metallic luster is lost and a sufficient decoration effect cannot be obtained. If it is 1 μm or more, it becomes conductive.

Such a sea / island structure is formed by entanglement of complicated conditions such as the generation and growth of nuclei of vapor deposition atoms and coalescence of islands. Although it is not impossible to set the island size and the island gap by selecting the vapor deposition metal material, the vapor deposition rate, and other vapor deposition conditions, quite complicated control is required and the material is limited.
In general, metals having low melting points and noble metals are relatively easy to control, and tin (Sn), zinc (Zn), tin-aluminum (Sn-Al) alloys, tin-silicon (Sn-Si) alloys are used. Of these, tin (Sn) is particularly easy.

FIG. 2B shows a regular island shape, but a deposited film formed as a continuous layer is formed into a regular island shape and an island gap by photoetching. Such a sea / island structure cannot be photo-etched when deposited on a paper substrate, so the layer formed on the plastic film is etched to form a transfer film and then transferred to the paper substrate.
Even in such a shape, the average island size of the islands 4a is preferably 20 nm to 1 μm, and the island gap 4b is preferably 10 nm to 500 nm. If the island size is smaller than 20 nm, the metallic luster is lost and a sufficient decoration effect cannot be obtained. The same is true if the thickness is 1 μm or more.

  In the case of a continuous vapor deposition layer, there are few restrictions on vapor deposition conditions, so a wide range of vapor deposition materials can be selected. Usually, as a material used, aluminum (Al), silver (Ag), tin (Sn), zinc (Zn), a tin-aluminum (Sn-Al) alloy, a tin-silicon (Sn-Si) alloy is preferably used. It is done. Among them, aluminum is generally used and the metallic luster is excellent.

  In addition to the photoetching method, there is a liftoff method. It is considered difficult to form a fine island structure by the masking method during vapor deposition. In the case of photoetching, etching can be performed to a size up to submicron, so that the island size and the gap between the islands can be reproduced. The shape of the island 4a is not a regular shape as shown in FIG. 5B, but can be designed to be an indefinite shape or a random shape so that moire does not occur.

Next, the manufacturing method of the book with an IC tag of the present invention will be described.
When the cover of a book is a paper material, direct vapor deposition is also performed, but it is known that the direct vapor deposition of paper has various problems as follows.

(1) Since the degree of vacuum does not increase at the time of vapor deposition due to moisture contained in the paper, it is necessary to treat the paper except for special paper with little moisture such as condenser paper. Vapor deposition is not possible.
(2) In the case of ordinary paper, it is necessary to dry the paper before vapor deposition. However, since it takes a long time, the cost is greatly increased. Moreover, since the original properties of paper are lost when dried, it is necessary to adjust the amount of water after vapor deposition.
(3) Since the paper surface is rough and vapor deposition particles enter the paper layer, it is necessary to apply a sealing coat to the paper surface before vapor deposition.
(4) Vapor deposition can be deposited on a large number of plastic films per batch, but in the case of paper, the thickness of the paper is several to several tens of times the thickness of the plastic film. It cannot be processed and the efficiency is greatly reduced.

However, in recent years, with the evolution of vapor deposition apparatuses and vapor deposition methods and improvement of materials, a considerable amount of direct vapor deposition on paper materials has been performed. There is also a method in which a vapor deposition layer is formed on a plastic film and transferred inline to a paper substrate with an adhesive in a separate vapor deposition chamber. Therefore, the present invention is premised on both direct vapor deposition and indirectly forming a vapor deposition layer on a paper material using a transfer film.
That is, the invention described in claim 1 includes both the case of direct vapor deposition and the case of transfer, and the invention described in claim 2 and claim 3 relates to a method by transfer. In the case of transfer, there are a case where the sea / island structure is directly deposited on the transfer film and a case where a continuous film is once deposited on the transfer film and then a photo-etching is performed to form a fine sea / island structure.

When directly vapor-depositing on paper, the following steps are performed: substrate pretreatment → drying → vacuum deposition → post treatment → humidification → deposition product → printing → cutting. The pretreatment of the base material is to perform a sealing coat.
As the paper substrate, coated paper, art paper, high-quality paper, glassine paper and the like are used.
In the vapor deposition product, the thickness of the vapor deposition layer is about 30 nm to 100 nm. Since it is not a close layer, there is an advantage that the amount used can be 1/1500 to 1/150 compared with 7 μm aluminum foil. Thereby, the same brightness as the aluminum foil can be obtained. In the case of sea / island structure deposition, tin (Sn), zinc (Zn), tin-aluminum (Sn-Al) alloy, tin-silicon (Sn-Si) alloy can be used, but tin is preferably used, and aluminum The same glitter effect can be obtained.

  When the sea / island structure is formed by photoetching, normal vapor deposition without the sea / island structure is performed on the plastic film surface. As the film, polypropylene, polyethylene, polyethylene terephthalate (PET) or the like can be used. Various deposition materials can be used in this case, and aluminum (Al), tin, zinc, tin-aluminum alloy, tin-silicon alloy, silver, gold, etc. can be deposited, but aluminum is the most common. Has been used. Colored vapor deposition is also possible, and a colored metallic feeling can be expressed by vapor-depositing a pigment or a dye colorant in advance and then depositing aluminum on the vapor deposition surface.

  In the case of aluminum (melting point: 660 ° C.), it is heated to 1400 ° C. or higher and evaporated to form a thin film having a thickness of 100 nm or less. The deposited film thus formed is photo-etched to form a minute sea / island structure. In the case of photo-etching, the island size can be set to a required size by keeping the inter-island gap constant.

  When using a sea-island structure vapor deposition film like a hot stamping foil, after forming a release layer on a material such as a PET film, aluminum deposition is performed, and then etching into the sea-island structure, A form in which a hot-melt adhesive is applied to the surface is preferable. The transfer of the hot stamping foil can be performed by providing a stamp on the hot plate according to the design and inserting the foil between the stamp and the transfer paper surface. A transfer method that does not use a stamp is also possible. That is, a method may be used in which an adhesive is applied in a pattern on the paper side to be transferred, and the vapor deposition layer is transferred by passing between pressure rollers.

Tin (Sn; melting point: 232 ° C.) was vacuum-deposited on the entire surface of the coated paper (90 kg / 46 size) so as to have a sea / island structure, and then a necessary pattern was offset printed. This vapor-deposited paper was used as a cover cover to cover the entire front and back cover of the book. The island size 4a on the vapor deposition surface was about 800 nm, the island gap 4b was about 400 nm, and the thickness was about 80 nm.
A non-contact IC tag ("Accumave (trademark)" (13.56 MHz) 2 manufactured by Dai Nippon Printing Co., Ltd.) 2 was attached to the back of the book 1 using an adhesive. A 25 μm thick aluminum foil is dry-laminated on a 38 μm polyethylene terephthalate (PET) film surface, the aluminum foil is photo-etched into a coil (6-turn) antenna pattern having an outer diameter of 450 mm × 760 mm, and IC chips are formed on both ends of the coil. And the surface is coated with a paper base material.

<Manufacture of transfer film>
One side of a 40 μm thick PET film (“Lumirror” manufactured by Toray Industries, Inc.) was coated with cellulose acetate butyrate-based primer coat, and then aluminum was vacuum-deposited into a continuous layer having a thickness of 80 nm. Thereafter, a photomask pattern having an irregular sea / island structure is exposed to form a resist film, and the aluminum deposited film is etched and washed with the resist film. The island size 4a is about 1 μm, and the island gap 4b. A transfer film having an aluminum vapor deposition layer having a sea / island structure of about 500 nm was obtained.

  When the PET film is peeled off after the vapor-deposited surface of the transfer film and the coated paper (110 kg / 46 size) on which the urethane resin adhesive has been partially applied are pressed, the adhesive application shape is obtained. Coated paper onto which the aluminum deposition layer was transferred was obtained. This coated paper was used for the cover 11 of a magazine, and the same non-contact IC tag 2 as that in Example 1 was attached to the facing portion using an adhesive.

For the book 1 with the non-contact IC tag of Example 1 and Example 2, a writing / reading test for the non-contact IC tag was performed from a position 5 cm away from the book. (13.56 MHz)) 5, it was confirmed that both could be written and read without any trouble. The result was the same even if the front and back sides of the book were reversed so that the side facing the IC tag reader / writer 5 was reversed.
In addition, when the surface resistivity of the vapor deposition layer of the cover cover of Example 1 and the cover of Example 2 was measured, it was confirmed that both were 10 ⁷ Ω / □ or more and had insulating properties.

It is a figure which shows the book with a non-contact IC tag of this invention. It is a figure explaining a sea and an island structure.

Explanation of symbols

1 book, 2 book contactless IC tag 3 IC chip 4 metal deposition layer 5 reader / writer

Claims (3)

In a book that has a design that includes a metal vapor deposition layer on the front cover, back cover, cover cover, or binding paper and that has a non-contact IC tag inside the book, the metal vapor deposition layer has a sea / island structure and has an insulating property. And
The sea-island structure of the metal vapor-deposited layer is formed into a sea-island structure by photoetching the vapor-deposited layer formed on the base film of the transfer foil, and the sea-island-structured vapor-deposited layer is covered on the front cover, back cover, cover cover or binding. A book with a non-contact IC tag , which has been transferred to paper . Water island structure of the metal deposition layer, an island size 20Nm～1myuemu, the non-contact IC tag with the claim 1 Symbol placement be an interval 10nm~500nm between the islands. The metal deposition layer is a deposition layer of aluminum (Al), silver (Ag), tin (Sn), zinc (Zn), tin-aluminum (Sn-Al) alloy, tin-silicon (Sn-Si) alloy. The book with a non-contact IC tag according to claim 1 or 2 , wherein the book has a contactless IC tag.

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