JP4029697B2 - IC chip assembly - Google Patents

Description

【００６７】
【発明の効果】
本発明のＩＣチップ実装体は、アンテナ回路およびＩＣを備えたＩＣチップ実装体であって、ＩＣを接続したアンテナ回路、アンテナ回路近傍に位置する誘電体層、誘電体層の外側に位置する透磁性材料を含む非導電性透磁性層を設け通信可能範囲内にしたので、金属表面上等、金属物体の近傍位置及び金属表面上でない位置等金属が周囲にない状態のいずれの位置、状態においても通信が可能となっている。
【図面の簡単な説明】
【図１】本発明の非接触ＩＣタグの一実施例の断面図である。
【図２】本発明の非接触ＩＣタグの別の一実施例の断面図である。
【図３】ＩＣ実装体とリーダーライタ間の通信可能距離と周波数の関係他を示す図。
【図４】フリーの場合のＩＣタグの通信の可否の評価を行う評価試験装置の概要を示す概略図。
【図５】金属板上に貼り付けた場合のＩＣタグの通信の可否の評価を行う評価試験装置の概要を示す概略図。
【符号の説明】
１ インレットシート用支持体
９ 中間層
１２ 回路パターン
１１ 非導電性透磁性層
６ ＩＣ[0001]
BACKGROUND OF THE INVENTION
The IC chip mounting body of the present invention relates to a non-contact type IC chip mounting body that is used for a ticket, a telephone card, a luggage tag, etc. and performs data communication, etc. by external radio waves, and further used for a bank card, a point card, etc. The present invention relates to a combination IC chip mounting body having both functions of the contact IC chip mounting body and the non-contact type.
[0002]
These IC chip mounted bodies are also called so-called data carriers, which are commonly called IC cards. However, they are not necessarily in the form of cards, but are not limited to sheet-like tags attached to objects or tags enclosed in containers. Various types of carriers such as a wristwatch type are also included. Also in this specification, the IC chip mounting body is used as including an IC card and a form other than a card shape.
[0003]
[Prior art]
In recent years, small electronic devices in which IC chips are mounted as new information recording media in commuter passes and the like used for personal information management, physical distribution management or commuting to school have been spreading. In particular, card-type large-capacity variable information recording media called IC cards that are convenient for portable use have begun to spread widely.
IC cards are large and can be classified into three types: contact type, non-contact type and combination type having both functions. The contact IC card has a data exchange metal terminal electrically connected to the IC chip on the card surface, and exchanges data with an external reader through the terminal. It is. Currently, disposable types are widely distributed as telephone cards in Europe and the like, and experiments using information rewritable types as money cards are being conducted in various countries. In particular, it is attracting attention as a card used in financial relations.
[0004]
On the other hand, non-contact type IC cards exchange data in a non-contact manner via radio waves, so that they are attracting attention as an alternative recording medium such as a conventional ticket, commuter pass, etc. that replaces a ticket with a magnetic recording layer provided on one side. Has been. In particular, it is expected that the convenience will be greatly improved because it is not necessary to take out the ticket one by one when passing through the ticket gates, and data can be exchanged even from regular entry or bag.
In the logistics field, management by IC carriers called RFID (Radio Frequency Identification) tags, which replaces barcodes and magnetic recording with radio waves and exchange data with mobile objects, is becoming mainstream. .
[0005]
[Problems to be solved by the invention]
When such a non-contact IC tag is attached to a metal casing or used in the vicinity of a metal object, there is a problem that communication with a reader / writer becomes impossible due to the influence of the metal.
[0006]
The object of the present invention is to solve the above problems, and to provide an IC chip mounting body capable of communication at any position without being affected by surrounding metal objects such as a position on the metal surface and a position not on the metal surface. There is to do.
[0007]
[Means for Solving the Problems]
An IC chip mounting body according to the present invention is an IC chip mounting body including an antenna circuit and an IC, and is an antenna circuit to which an IC is connected, a layer positioned on the antenna circuit , and paper containing voids, synthetic An intermediate layer made of paper or cloth and acting as a dielectric layer , and a non-conductive magnetically permeable layer including a magnetically permeable material located outside the intermediate layer .
Furthermore, it is preferable that the non-conductive magnetic permeable layer is a layer containing a magnetic permeable material in an island shape.
Further, the magnetically permeable material is preferably at least one material selected from ferrite, silicon steel, Sendust alloy, Fe—Al alloy, electromagnetic soft iron, carbonyl iron, amorphous alloy, and permalloy.
[0008]
DETAILED DESCRIPTION OF THE INVENTION
The present inventors basically have the above problem due to the formation of a dielectric layer-non-conductive magnetic permeable layer between the IC chip mounting body and the metal casing to which the IC chip mounting body is attached. It has been found that this can be solved, and the IC chip mounting body of the present invention can be provided.
As the heart of the IC chip mounting body, an IC called an inlet sheet and an antenna circuit portion such as a coil shape, a dipole shape, a flat plate shape, etc., for exchanging signals and power with the outside are used.
[0009]
The present invention can be used in both non-contact type and combination type IC chip mounting bodies. Among them, a non-contact type IC tag suitable for use of the present invention and a circuit substrate used therein Will be described.
First, the process from the circuit substrate to the formation of the inlet sheet will be described.
[0010]
1. A circuit substrate is formed by forming a circuit pattern on the support of the inlet sheet by etching from the circuit substrate to the formation of the inlet sheet, other methods, or a combination thereof. A sheet on which an electronic component such as an IC chip, a capacitor, or an antenna circuit is mounted or formed on the circuit substrate is referred to as an “inlet sheet”.
[0011]
Hereinafter, (1) the manufacturing process from the circuit substrate to the inlet sheet of the present invention will be described step by step, followed by (2) the assembly of the IC card.
First, the metal foil and the support constituting the circuit substrate will be described in detail.
Manufacture and process of inlets [0012]
[Metal foil]
The metal foil used is aluminum foil, copper foil, gold foil, silver foil, zinc foil, nickel foil, tin foil, manufactured by electrolytic method, rolling method, precision rolling method, punching foil method (mainly for arts and crafts) Alloy foil or the like is preferable.
In general, these metal foils are preferably subjected to an easy adhesion treatment on the side to be bonded to the base material. The larger the unevenness due to the easy adhesion treatment, the higher the adhesive strength. However, if it is too large, the strength of the metal foil may be weakened. When a thin metal foil is used, fine irregularities may occur on the surface of the metal foil, which may cause problems with the reproducibility of thin lines.
[0013]
Moreover, since metal foil is normally surface oxidized by air, it is preferable to perform an antioxidant treatment. On the other hand, aluminum is stabilized by forming an aluminum oxide film on the surface, and no special surface treatment is required.
[0014]
In general, metal foils used for etching patterns are mostly copper foils and aluminum foils. There are two types of copper foil: rolled copper foil (including precision rolling) and electrolytic copper foil.
Rolled copper foil has good mechanical strength against repeated bending and is suitable for wiring of moving parts such as computer hard disks and printers. Electrolytic copper foil has poor bending resistance compared to rolled copper foil, but the cost is low. In the example IC mounting body used in the present invention, since it is not used to be bent, even an electrolytic copper foil can be used sufficiently.
[0015]
Aluminum foil is manufactured by rolling. Aluminum has a higher stretchability than copper and is preferable because it can be easily caulked. The cost is about 1/5, which is very preferable from the viewpoint of cost reduction.
However, since the specific resistance of aluminum is as high as about 1.5 times that of copper, it is necessary to increase the thickness and the width of the circuit in order to obtain the same resistance value.
[0016]
[Inlet sheet support]
The support for the inlet sheet is selected from an electrically insulating material. The support can be roughly divided into a rigid substrate and a flexible substrate.
The rigid substrate is manufactured by impregnating aramid fiber or glass fiber sheet with a thermosetting resin such as an epoxy resin, and impregnating paper with a thermosetting resin such as a phenol resin and applying heat and pressure to cure. The rigid substrate has a high elastic modulus with respect to mechanical stress.
[0017]
On the other hand, a flexible board is a circuit board on a film-like support, and is used for printer heads and wiring in cars. in use.
Paper, nonwoven fabric, woven fabric, film, glass epoxy substrate, paper phenol substrate and the like can be used as the support, and a circuit pattern is created by etching, printing, conducting wire, vapor deposition, plating, etc. of metal foil. Any circuit board may be used, but in terms of cost, general-purpose films such as PET (polyethylene terephthalate), PEN (polyethylene tenaphthalate), PPS (polyphenylene sulfide), PBT (polybutylene terephthalate), PC (Polycarbonate), ABS (acrylonitrile-butadiene-styrene), PVC (polyvinyl chloride), PET-G (modified polyester resin obtained by polymerizing at least three components of ethylene glycol, terephthalic acid and 1,4-cyclohexanedimethanol), Those made of materials such as PP (polypropylene), PE (polyethylene), and polyimide are preferred.
[0018]
In addition, it is preferable that the adhesive surface side of the support for the inlet sheet with the metal foil layer, the conductive ink or the like is subjected to easy adhesion treatment. That is, the easy adhesion treatment is to provide a surface treatment for improving the adhesive strength by providing surface irregularities on the surface of the support for the inlet sheet that is bonded to the circuit by chemical treatment or physical treatment.
[0019]
[Inlet sheet]
After a part of the metal foil of the circuit base material obtained by bonding the support and the metal foil as described above is removed by etching to form a circuit pattern including the necessary antenna circuit, the circuit pattern of the IC chip is The inlet sheet can be obtained by mounting on the formed substrate. The inlet sheet becomes a heart component when assembling the non-contact type IC tag described below.
[0020]
A circuit pattern including an antenna circuit can be formed as follows. A photosensitive resin layer is provided on the metal foil of the circuit substrate, and the circuit pattern is printed on the photosensitive resin layer using a negative or positive photographic film or a chrome film mask, or printing, lettering, etc. The circuit pattern is directly drawn on the metal foil of the circuit board by the various methods. By using the circuit pattern formed in this way as a mask, the unnecessary metal portion except for the circuit pattern portion is dissolved by so-called etching using a ferric chloride solution or a caustic soda solution, so that it is necessary for the metal foil. The circuit pattern 12 can be formed to produce an etched circuit substrate.
[0021]
The circuit substrate can also be made from a circuit substrate obtained by bonding metal foils on both sides. With such a circuit substrate, it is possible to form a planar capacitor on the circuit substrate. A planar capacitor is a very useful component when tuning for accurately matching frequencies in a non-contact type IC tag. A circuit substrate in which metal foils are bonded to both sides can be used by forming a three-dimensional circuit by conducting both metal foils by a method of conducting by through-hole plating, mechanical, or welding.
In addition to the method for forming a circuit pattern including an antenna circuit by the etching method described above, the circuit pattern can be formed by the following method. Therefore, a circuit pattern including an antenna circuit can be formed by combining these methods alone or in combination.
[0022]
[Conductive ink]
In this method, an antenna circuit or the like is formed by mixing a metal powder such as silver or copper and a resin, and printing by screen printing or the like. Since the resistance value at the same cross-sectional area is about 10 times higher than that of the metal foil, it may not be used depending on the chip used.
[0023]
[Metal wire]
Although it is the cheapest material, it requires a high level of technology for mounting bare chips, and when the resistance value is comparable to that of an etching circuit, the wire diameter becomes considerably large.
[0024]
[plating]
Since the circuit is formed through a substrate such as non-woven fabric or nylon mesh, the thickness of the metal can be increased, but it is basically the same as single-sided etching, and the bare chip has recently been miniaturized. However, there is a drawback that a flat capacitor cannot be provided, but the cost is relatively low and there is a possibility that it will be widely used in the future.
[0025]
[Metal powder]
In this method, metal powder is directly applied in a circuit pattern, but the productivity is low and the cost is high.
[0026]
[Vapor deposition]
In this method, the metal is heated to vapor in a high vacuum, and deposited on a film, etc., but the metal film is thin, and the resistance value of the antenna is too high for the currently used IC chip, making it difficult to produce a communication distance. There is a problem.
On the other hand, there is a method called sputtering. Although it is similar to the above-mentioned vapor deposition method, it is a method in which a rare gas such as argon is put in a high vacuum and the rare gas molecules are collided with a metal called a target at high speed to deposit the metal on the substrate. When this method is used, it is possible to obtain a metal film having a sufficient thickness to drive the IC chip as compared with the vapor deposition method.
[0027]
[Connection between IC and circuit pattern]
In the present invention, a bare chip is heated by using a bonding resin such as ACF (Anisotropic Conductive Film), ACP (Anisotropic Conductive Paste), NCP (Non-Conductive Paste), or by using a metal such as solder. A regular connection method such as a connection method, a connection method using a conductive adhesive containing a metal powder such as silver or copper, ultrasonic bonding, welding, or thermocompression bonding between metals can be used.
When the package chip described below is used, the antenna circuit is connected to the antenna circuit in the same manner as described above by heat connection using a metal such as solder, or contains metal powder such as silver or copper. It is possible to use a conventional connection method such as a method of connecting with a conductive adhesive, ultrasonic bonding, welding, or thermocompression bonding between metals.
[0028]
Hereinafter, components such as ICs related to the manufacture of the inlet sheet will be briefly described.
[IC]
IC chips used in the present invention include bare chips of 135 kHz, 4.9 MHz, 6.5 MHz, 13.56 MHz, 2.54 GHz band and the like. The IC used for the IC chip mounting body is a form of bare chip in which bumps are provided on the chip. The chip is die-bonded to a lead frame material that can also be used as a terminal part, and between the pad part of the chip and the lead frame with a gold wire or the like After being wired, it is supplied in a form called a package chip that is sealed with an epoxy resin or the like or fixed on a film with terminals. Recently, an IC called a CSP (chip size package) having a shape similar to a bare chip has been developed. This CSP in which a bare chip is sealed with a resin and a new electrode is provided is a technique that has been conceived because of recent improvements in semiconductor integration, and CSP can also be used as the IC chip of the present invention.
[0029]
2. IC Tag Material / Process The material / process used from the inlet sheet described above to the IC tag will be described below.
A basic configuration diagram of an IC tag is shown in FIG. FIG. 1 is a cross-sectional view of an example of a non-contact IC tag according to the present invention. A cover layer 8 is formed on one side of an inlet sheet (mainly composed of a support 1, a circuit pattern 12, and an IC 6) via an adhesive layer 10a. Are joined. An intermediate layer 9 and a nonconductive magnetically permeable layer 11 are laminated on the opposite side of the inlet sheet with respect to the coating layer 8. The coating layer 8 can be provided with a printing layer and a protective layer 7 on the outside thereof. Adhesive layers 10b, 10c, and 10d for joining the layers and the release paper 13 are appropriately provided between the layers.
[0030]
(Coating layer)
The covering layer 8 is a base material of the outermost shell of the completed IC tag, and a printing layer, a magnetic layer, a seal, a protective layer 7 and the like can be further provided as necessary. Film or sheet-like polyester, polycarbonate, ABS, PET-G, polyvinyl chloride, polyethylene, polypropylene, nylon, polyimide, polystyrene, polymer alloy, engineering plastics and other plastic films, paper, nets, non-woven fabrics, etc. A composite, a base material in which glass fiber or paper is impregnated with an epoxy resin or the like can be used. Moreover, depending on the laminated structure of a tag, it may serve as a support body. The coating layer can be transparent, translucent or opaque depending on the application. Most of the translucent and opaque plastic films that are in circulation are white pigments such as titanium oxide, calcium carbonate, silica, and organic pigments kneaded in the resin, or a concealing layer by printing or coating on the surface. Is provided. Furthermore, a functional surface coat such as heat-sensitive, thermal transfer, and inkjet may be applied.
[0031]
Note that general information such as ruled lines, instructions, and service marks can be printed on the coating layer. Examples of this printing method include printing methods and printing machines such as offset printing, gravure printing, letterpress printing, screen printing, flexographic printing, etc., and various methods can be used for printing ink and drying, but UV ink is used. UV printing which is dried by UV irradiation is preferred.
[0032]
In addition, as a method for displaying necessary information such as a name, serial number, and delivery destination, this coating layer can be printed using a recording device. Examples of the recording device include a printer such as an ink jet method, an ink ribbon method, a thermal transfer method, an electrophotographic method, a thermal recording method, and a pressure sensitive recording method, an impact type dot printer, a copying machine, a laser engraving machine, and the like.
[0033]
[Adhesive layer]
The adhesive layers 10a, 10b, and 10c are layers having a function of adhering the inlet sheet support 1 and the covering layer 8, the intermediate layer 9 and the non-conductive magnetic permeable layer 11 and the like. The adhesive resin used for the adhesive layer is a thermosetting resin such as an epoxy resin, a commonly used dry laminating adhesive such as polyester, ABS, acrylic or polyurethane, or a hot melt resin and a thermosetting resin. Hygroscopic curable resins and linear curable resins are preferred. In some cases, the adhesive layer may be adhered to each film with an adhesive for wet lamination.
In addition, when the tag is attached to a metal surface or a surface coated with metal, an adhesive having stronger tackiness, a so-called adhesive is used for the adhesive layer 10d. The adhesive is provided on the base material, is sandwiched between release papers 13 to which a release agent is applied, and is peeled off when the IC tag is actually attached to an article.
[0034]
As the mold release agent, a water dispersible mold release agent is preferable. For example, a polybutadiene rubber, styrene-butadiene copolymer, alkyd-silicone copolymer, acrylic-silicone copolymer release treatment agent, In addition to inks containing release agents such as release varnish and medium, waxes such as acrylic ester resin latex, zinc stearate, calcium stearate, stearamide, ethylene-bis stearamide, paraffin, polyethylene, polypropylene, etc. And mixtures of the above waxes with water-soluble polymers such as polyvinyl alcohol. These release agents may be used alone or in combination of two or more.
[0035]
Among the adhesives, so-called pressure-sensitive adhesives such as rubber-based, acrylic-based, silicone-based, and the like, solvent type, emulsion type, hot-melt type and the like are used. In order to form an adhesive layer, the adhesive may be applied to a release sheet, dried as necessary to form an adhesive layer, and then bonded to the surface substrate, or directly applied to the surface substrate. . In the case of having a heat-sensitive recording layer as a surface base material, the former method of applying to the release sheet is preferred.
[0036]
As the adhesive coating apparatus, for example, a roll coater, knife coater, bar coater, die coater, comma coater, lip coater, reverse gravure coater, vario gravure coater, etc. are used as appropriate, and the coating amount of the adhesive is The dry weight is adjusted in the range of about 5 to 50 g / m ^2, but it is necessary to have an adhesive force between the base sheet and the adherend that does not peel off when attached to the adherend. is there.
[0037]
As the base material of the release sheet covering the adhesive, for example, casein, dextrin, starch, carboxymethylcellulose, methylcellulose, ethylcellulose, hydroxyethylcellulose, high-density base paper such as glassine paper, clay-coated paper, kraft paper, or high-quality paper Natural polymers such as polyvinyl alcohol, styrene-butadiene copolymer, methyl methacrylate-butadiene copolymer, ethylene-vinyl chloride copolymer, ethylene-vinyl acetate copolymer, acrylate ester copolymer, or synthetic resin It is possible to use a release substrate provided with a sealing layer mainly composed of pigment, polylaminated paper laminated with polyethylene etc. on kraft paper or fine paper, or film of polypropylene, polyethylene terephthalate, etc., water dispersion type , Solvent type There after coated about 0.05 to 3 g / m ² by dry weight a release agent such as a solventless type silicone resin or a fluorine resin, obtained by forming a release agent layer by heat curing or ionization radiation curing or the like is used The The coating apparatus for coating the release agent is not particularly limited. For example, a bar coater, a direct gravure coater, an offset gravure coater, an air knife coater, a multi-stage roll coater, or the like is used as appropriate.
[0038]
[Intermediate layer: Dielectric layer]
As the intermediate layer 9, a layer made mainly of a polymer material, which will be described later, is used. This layer mainly acts as the dielectric layer of the present invention. When the inlet sheet described above and a non-conductive permeable layer 11 described later are overlapped, the resonance point shifts to the low frequency side because the non-conductive permeable layer 11 has a relatively large dielectric constant. In order to prevent this, it has been found that an intermediate layer 9 having a low dielectric constant (ε) is preferably interposed between the inlet sheet and the nonconductive magnetic permeable layer. The electrostatic capacity (C) is expressed by C∝ε and is proportional to the dielectric constant. The lower the dielectric constant, the smaller the electrostatic capacity.
The resonance point frequency (f) is expressed as f∝1 / C ^1/2 and is inversely proportional to the square root of the capacitance, and the resonance point increases as the capacitance decreases. By this principle, it is possible to reduce the floating capacitance of the inlet sheet by lowering the dielectric constant of the dielectric layer, and the resonance point shifted to the low frequency side due to the non-conductive magnetic permeable layer. It is intended to return to the high frequency side.
[0039]
FIG. 3 shows the relationship between the communicable distance between the IC package and the reader / writer and the frequency. Furthermore, the relationship between the loss amount of electromagnetic wave energy and the frequency seen from the reader / writer is shown by a solid line in the figure. In FIG. 3, the dotted line indicates the relationship between the communicable distance and the frequency between the IC mounting body and the reader / writer. In this figure, the communication distance is within a range of approximately 12 to 15 MHz with the resonance point of 13.5 MHz as the maximum, d: Communication frequency range. The solid line indicates the amount of loss of electromagnetic wave energy as viewed from the reader / writer (R / W) with respect to the IC mounting body of each configuration with respect to the frequency. There are four types of solid lines, A1, A2, B1, and B2. A1: Near the resonance point when the IC mounting body that does not use the dielectric layer is in space (not on or near the metal surface), A2: Near the resonance point when the IC mounting body of the configuration is on the metal surface, B1: Near the resonance point when the IC mounting body of the configuration using the dielectric layer is in space (not on or near the metal surface), B2: The state of the loss amount of electromagnetic wave energy near the resonance point when the IC mounting body having the same configuration is on the metal surface is shown. This solid line shows the amount of electromagnetic energy loss as seen from the reader / writer, so the valley of each solid line in the figure where the amount is maximum communicates with the IC mounting body at maximum efficiency at the valley frequency (resonance point). It shows what you can do. Furthermore, since the IC mounting body having the efficiency using the dielectric layers indicated by B1 and B2 has deeper valleys, the IC mounting body can communicate more efficiently. After all, this figure shows that communication between the reader / writer and the IC package is possible as long as the resonance frequency of the IC package is within the communicable frequency range of the reader / writer. It can be seen that the IC package having the configuration using the dielectric layer shown can communicate more efficiently regardless of the presence or absence of metal.
[0040]
The present inventors can make use of this fact to try to solve the problem by controlling the resonance frequency of the IC mounting body in the environment both in the metal surface and in the vicinity and in the space and within the communicable frequency range. It was. Specifically, the resonance frequency as an IC mounting body shifts to a low resonance frequency at which communication is impossible only by bonding only the inlet sheet and a non-conductive magnetic permeability layer described later (see A1 in the figure). On the other hand, this dielectric layer is used, and control is performed so that it is increased to some extent so as to fall within a communicable resonance frequency range by adjusting such as increasing the thickness of this layer or lowering the dielectric constant of the layer (see FIG. Middle B1). In addition, when used by being affixed to a metal surface, the resonance frequency of the IC mounting body tends to shift to a high resonance frequency at which communication is impossible. By appropriately designing the above-mentioned points for the above-mentioned dielectric layer so as to obtain a lower resonance frequency, communication can be performed more efficiently in both the metal surface, the vicinity, and the environment in the space (in the figure). B2).
[0041]
As described above, the intermediate layer mainly functions as a dielectric layer, but this exists in the vicinity of the circuit pattern 3 and the circuit pattern 3 including the antenna circuit and the non-conductive magnetically permeable layer 4. If the layers have dielectric properties, these layers are combined to act as a dielectric layer, which is described as such. In other words, these layers near the antenna circuit also contribute as dielectric layers when the dielectric constant is small.
Actually, for example, an adhesive layer for bonding each layer other than the intermediate layer is thin, so that the contribution as the dielectric layer is small. Among these layers, the intermediate layer 2 and the inlet sheet support 1 mainly act as dielectric layers in that they are relatively thick layers and are close to the antenna circuit.
[0042]
However, what should be noted here is the position of the support 1 for the inlet sheet in the IC tag. 2 shows a cross-sectional view of another example of the non-contact IC tag of the present invention. In FIG. 2, the inlet sheet support 1 includes a circuit pattern including an antenna circuit as compared with the direction of the inlet of FIG. 3 is an example of a non-contact IC tag that is positioned on the non-conductive magnetically permeable layer side with respect to FIG. When the inlet sheet support 1 is interposed between the circuit pattern 3 and the non-conductive magnetically permeable layer 4 as shown in FIG. 2, the contribution as a dielectric layer becomes larger, but the inlet as shown in FIG. When the sheet support 1 is not interposed between the circuit pattern 3 and the nonconductive magnetically permeable layer, the contribution as a dielectric layer is relatively small. Therefore, in the end, it is the intermediate layer and / or inlet sheet support that substantially acts as the dielectric layer of the present invention. A sufficiently thick intermediate layer located between the antenna circuit and the non-conductive magnetically permeable layer is substantially a dielectric layer. Similarly, the support for the inlet sheet having a sufficient thickness located between the antenna circuit and the nonconductive magnetically permeable layer is also substantially a dielectric layer. Eventually, in order to obtain the effects of the present invention, selection of such a structure and selection of the material and thickness of the intermediate layer and inlet sheet support are important. In addition to these combinations, it is necessary to select in consideration of combinations with parameters such as IC chips to be used and frequencies of radio waves to be used.
[0043]
In order to control the floating capacitance of the intermediate layer and inlet sheet support, the material of each layer is selected. Dielectrics include polyethylene, chlorinated polyethylene, polypropylene, polyurethane, acrylic, styrene, PET, PEN, PET-G, ABS, vinyl chloride, vinyl acetate, EVA, polycarbonate, alloy films, paper, nonwoven fabric, woven fabric, Alternatively, a mixture of these materials with commonly used organic / inorganic materials such as silica, calcium carbonate, titanium oxide, and carbon black can also be used. Among these, polypropylene and polyethylene are more preferably used because of their relatively low dielectric constant and low cost.
[0044]
Each adhesive layer also functions in principle as a dielectric layer, but since it is usually very thin, its contribution as a dielectric layer is very small.
Further, by containing a large amount of voids in the dielectric layer such as the intermediate layer or the support for the inlet sheet, the influence of air having a low dielectric constant can be more strongly affected. Examples of such a material include a film in which a pigment is kneaded and stretched to form a lot of voids, such as YUPO (synthetic paper manufactured by YUPO CORPORATION ), paper , foamed paper, non-woven fabric, and cloth.
[0045]
[Non-conductive magnetically permeable layer]
The non-conductive magnetic permeable layer performs its function when the IC mounting body is provided in close contact with the metal surface. The non-conductive magnetically permeable layer serves to transmit the signal from the reader / writer to the antenna circuit by passing the signal through the layer before being reflected on the metal surface. On the other hand, when the IC mounting body is not on the metal surface, the signal from the reader / writer passes through this layer in the same manner as the case where the IC mounting body is provided on the metal surface described above, and a part of this layer And the signal is transmitted to the antenna circuit. The non-conductive magnetic permeable layer 11 uses a non-electrically conductive sheet obtained by kneading ferrite, metal magnetic powder or flakes with high magnetic permeability into a resin. It is preferred initial permeability mu _a particularly nonconductive magnetically permeable layer in order to improve the transmission when the signal from the reader writer is weak is large. Therefore the initial permeability mu _a initial non-conductive magnetically permeable layer greater than 1, it is good is preferably 2 or more. In practice, a magnetically permeable metal material having a high magnetic permeability is not continuously connected but exists discontinuously. In other words, the resin portion becomes the sea and becomes a layer containing magnetic powder in an island shape so that electrical conductivity does not occur. The term “electric conductivity” as used herein refers to a volume resistance value of about 10 ² Ω · cm as a boundary, and a value exceeding this value is non-conductive.
[0046]
This is electrically conductive. For example, when an amorphous alloy sheet is used instead of the non-conductive magnetic permeable layer, the radio wave transmitted from the reader / writer is reflected on the surface of the conductive amorphous alloy sheet, This is because it is considered inconvenient because no signal and power are supplied to the antenna.
As the shape of the magnetically permeable material, magnetic powder or flake can be considered. As specific materials, ferrite, silicon steel, sendust alloy, Fe-Al alloy, electromagnetic soft iron, amorphous alloy, permalloy, and carbonyl iron can be used.
[0047]
Examples of the ferrite include Mn—Zn, Mn—Mg, and Ni—Zn. As the sendust / Fe—Al alloy, alpalm, hypermal, sendust, super sendust, and the like are used. As the electromagnetic soft iron, industrial pure iron, armco steel, low carbon steel and the like are used. As the amorphous alloy, cobalt-based, iron-based and nickel-based alloys can be used. As the composition of the amorphous alloy, 70 to 98% by weight of Co, Fe, and Ni are the main components, B, Si, and P are contained in a total of 2 to 30% by weight, and Al, Mn, Zr, and Nb are also contained. . As permalloy, 78-Permalloy, 45-Permalloy, 36-Permalloy, Cr-Permalloy, Mo-Permalloy, Supermalloy, and soft magnetic ferrite include Mn-Mg based alloy, Mn-Zn based alloy, Ni-Zn based alloy, etc. Can be used.
[0048]
Other components used in the non-conductive magnetic permeable layer are polyethylene, chlorinated polyethylene, polypropylene, polyurethane, acrylic, styrene, PET, PEN, PET-G, ABS, PVC, PVC, EVA Any resin can be used as long as it is a resin generally mixed with pigments, such as polycarbonate and alloy.
[0049]
Other materials include auxiliary agents that improve the affinity (adhesion) between the resin and magnetic powder, as well as antioxidants, lubricants, mold release agents, antifoaming agents, wetting agents, curing agents, and UV absorbers. An additive necessary for the manufacturing process and an additive for improving durability and convenience may be included.
[0050]
There are roughly two methods for producing the non-conductive magnetic permeable layer. One method is a method of applying a magnetic paint on a base sheet, and the other is a method of kneading a magnetic powder into a liquid resin such as heat melting using a device such as a kneader. .
When manufacturing by the coating method, when the magnetic powder to be used is a metal powder, when using it as a water-based paint, since the metal powder reacts with water, the coating using a solvent is common. When a non-conductive permeable layer is formed by coating, the thickness of the non-conductive permeable layer obtained by one coating is thin, and it is necessary to apply a number of times depending on the type of magnetic powder used.
[0051]
The method for forming the non-conductive magnetic permeable layer in which the resin and the magnetic powder are kneaded can be manufactured by the same method as that for manufacturing an ordinary resin film. For example, when a resin is melted by heat to form a sheet, a resin containing high-temperature magnetic powder is extruded with an extruder or the like, and uniaxially, biaxially stretched or unstretched into a sheet shape. Since 100% resin has a high viscosity and is quickly set by cooling, unlike a coating method, it is easy to produce a thick sheet.
Also, by using magnetic powder with good magnetic permeability, the non-conductive magnetic permeable layer can be thinned and the stress applied to the adhesive surface can be reduced when affixing to a surface with curvature, so there is no edge lift etc. When bonded to the surface, it becomes difficult to peel off over a long period of time.
[0052]
The size of each of the layers, the dielectric layer, and the non-conductive magnetic permeable layer may be any size as long as it substantially overlaps the antenna circuit having the circuit pattern. Usually, each layer is formed into a sheet shape having the same size as the outer edge of the non-contact IC chip mounting body.
[0053]
[Bonding]
In order to assemble as a tag, the above-mentioned constituent materials are bonded together. Since the non-conductive magnetic permeable layer 11 has an effect of blocking the signal from the reader / writer, the front and back sides of this tag exist. When the surface on the inlet sheet side of the non-conductive magnetic permeable layer 11 is a front surface, the opposite surface is the back surface on which the adhesive layer 10d that adheres to the adherend is provided. Comparing the communication with the reader / writer from the front side and the back side, if the signal of the reader / writer is weak, reading from the back side may not be possible.
[0054]
The constituent materials may be bonded to each other in the form of a sheet, or the materials supplied by a roll can be bonded to each other.
When using an adhesive or each layer material provided with an adhesive in advance, the release paper is peeled off and bonded with a rubber nip roll or the like so that air does not enter. In this case, it should be noted that since the chip is mounted on the inlet sheet, pressure is not applied more than necessary. Since various materials are bonded together, several steps are necessary.
[0055]
When a hot melt adhesive is used, it is possible to sandwich a solid adhesive sheet between the materials and bond them at a time by hot pressing. In the case of this method, a material having no heat resistance cannot be used.
It is also possible to bond each material while applying an adhesive. Although it is similar to the method of bonding with an adhesive, heat may be applied to some extent to cure the adhesive. Compared with the method using an adhesive, the adhesive strength between layers can be improved and the uneven thickness of the inlet sheet can be reduced, but the process becomes complicated and the yield decreases.
Moreover, these methods can also be bonded together combining suitably.
[0056]
[Punching]
To tag one by one from a molded sheet, it can be cut into a card shape one by one with electric, pneumatic, Thomson blades, male and female blades attached to a hydraulic press.
[0057]
【Example】
Hereinafter, the present invention will be described more specifically with reference to examples. However, the present invention is not limited thereto.
[0058]
Example 1
In Example 1, a non-contact IC tag was produced. The first embodiment will be described with reference to FIG. 1 described above. As shown in FIG. 1, a circuit pattern 12 including a loop antenna made of aluminum foil is provided on an inlet sheet base material 1 (thickness 50 μm) using PET by an etching method, and a through hole portion is provided as a circuit board. A film-like curable resin layer is temporarily pasted on the electrical connection terminals of the circuit board, and the bare IC chips 6 are sequentially temporarily placed thereon by a face-down method, and then the curable resin layer is cured. An inlet with a different configuration was used. This inlet was an ISO15693-compliant inlet sheet (trade name: TagIT HFI mini, manufactured by Texas Instruments).
[0059]
Next, an ink-compatible YUPO (inorganic pigment +) in which an adhesive material layer is provided on one side in which the coating layer 8 and the adhesive layer 10a are combined on the surface where the inlet chip obtained by the above operation is not mounted. Synthetic paper made of polypropylene) Ink-jet tack paper (Yupo thickness 80 μm, inkjet receptive layer thickness 30 μm, adhesive layer thickness 20 μm, manufactured by YUPO Corporation) was bonded. Adhesive layer (thickness) as an adhesive layer 10b on YUPO (inorganic pigment + polypropylene synthetic paper, trade name: SGS110, thickness 110 μm, manufactured by YUPO Corporation) which becomes the intermediate layer 9 on the opposite surface of the inlet to the inkjet receiving layer side The sheet | seat provided with 20 micrometers was bonded together. Magnetic sheet prepared by kneading Mn-Zn ferrite powder as a magnetic material on chlorinated polyethylene to be non-conductive magnetically permeable layer 11 subjected to processing for providing adhesive layers on both sides as adhesive layers 10c and 10d (trade name: noise countermeasures) Sheet PE45 manufactured by FDK Co., Ltd., non-conductive magnetically permeable layer part thickness 400 μm, volume resistance value 10 ⁷ Ω · cm, μ _a : 10, each adhesive layer thickness 45 μm, was bonded to the intermediate layer 9. A release paper 13 is bonded to the non-conductive magnetic permeable layer 11 on the adhesive layer 10d side.
Next, the sheet obtained as described above was punched out into a size of 30 mm × 54 mm with a Thomson blade to obtain a non-contact type IC tag.
[0060]
1 and 2, each layer is drawn in parallel. However, particularly in the vicinity of the IC 6, the thickness of the IC is thicker than that of the adhesive layer, so that the covering layer and the intermediate layer are locally recessed. It is processed so that the thickness is absorbed and the surface is not uneven.
[0061]
(Example 2)
As shown in FIG. 2, a contactless IC tag of Example 2 was produced in the same manner as in Example 1 except that the inlet sheet was laminated so that the chip mounting surface was positioned on the coating layer side.
[0062]
(Comparative Example 1)
A non-contact IC tag was produced in the same manner as in Example 1 except that the intermediate layer 9 and the adhesive layer 10b were not used in the production of the non-contact IC tag of Example 1.
[0063]
(Comparative Example 2)
Conductive amorphous alloy ribbon (trade name: amorphous magnetic shield tape, manufactured by Hitachi Ferrite Electronics Co., Ltd., amorphous alloy thickness 20 μm, adhesive layer thickness 45 μm, volume resistivity 1.3) instead of non-conductive magnetic permeability layer A non-contact IC tag was produced in the same manner as in Example 1 except that × 10 ⁻⁶ Ω · m) was used.
[0064]
(Evaluation)
The samples prepared in Examples and Comparative Examples were measured by the following method.
[0065]
Communication availability The communication availability was determined using the evaluation test apparatus shown in FIGS. A weak reader / writer 142 (RI-K10-001A, manufactured by Texas Instruments) was connected to a PC (personal computer) 141. The evaluation test was performed in two states, a case where the non-contact IC tag 103 was affixed on the metal plate 104 (a SUS304 plate having a 5 cm square and a 1 mm thickness) and a case where the contactless IC tag 103 was free (a state suspended by a string in the air). FIG. 5 shows an outline of an evaluation test apparatus when it is attached to a metal plate. FIG. 4 shows an outline of an evaluation test apparatus in a state where it is suspended from a support rod (not shown) by a string 101 in the air. In each state, “○” indicates that the distance between the antenna of the reader / writer and the tag is 0 to 10 mm, and “×” indicates that the tag cannot be read.
The above measurement results are summarized in Table 1 below.
[0066]
[Table 1]

[0067]
【The invention's effect】
An IC chip mounting body according to the present invention is an IC chip mounting body including an antenna circuit and an IC, and includes an antenna circuit to which the IC is connected, a dielectric layer positioned near the antenna circuit, and a transparent layer positioned outside the dielectric layer. Since a non-conductive permeable layer containing a magnetic material is provided and within the communicable range, in any position or state where the metal is not in the surroundings, such as a position near the metal object, a position not on the metal surface, etc. Can also communicate.
[Brief description of the drawings]
FIG. 1 is a cross-sectional view of an embodiment of a contactless IC tag of the present invention.
FIG. 2 is a cross-sectional view of another embodiment of the non-contact IC tag of the present invention.
FIG. 3 is a diagram showing the relationship between the communicable distance and frequency between the IC mounted body and the reader / writer, and the like.
FIG. 4 is a schematic diagram showing an outline of an evaluation test apparatus that evaluates whether or not IC tag communication is possible when free.
FIG. 5 is a schematic diagram showing an outline of an evaluation test apparatus that evaluates whether or not an IC tag can communicate when attached to a metal plate.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 Support body for inlet sheets 9 Intermediate | middle layer 12 Circuit pattern 11 Nonelectroconductive magnetic permeability layer 6 IC

Claims (3)

An IC chip mounting body including an antenna circuit and an IC, the antenna circuit connected to the IC, a layer positioned on the antenna circuit, and made of paper containing voids, synthetic paper or cloth, as a dielectric layer An IC chip mounting body comprising a working intermediate layer , and a non-conductive magnetic permeable layer containing a magnetic permeable metal material located outside the intermediate layer . 2. The IC chip mounting body according to claim 1, wherein the non-conductive magnetic permeable layer is a layer containing a magnetic permeable material in an island shape. The IC chip mounting body according to claim 1 or 2, wherein the magnetically permeable material is at least one material selected from ferrite, silicon steel, Sendust alloy, Fe-Al alloy, electromagnetic soft iron, carbonyl iron, amorphous alloy, and permalloy.

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