JP3642608B2 - IC card - Google Patents

Description

[0001]
[Industrial application fields]
The present invention relates to an IC card used for various applications, and more particularly to an IC card that can reduce the thickness of the card at a low cost in a non-contact IC card with a built-in coil.
[0002]
[Prior art]
In recent years, IC cards have been widely used for bank cash cards, telephone cards, various credit cards, various prepaid cards and the like due to their large storage capacity and ease of use. Such an IC card includes a contact type (contact type) card in which an electrode (connection terminal) that is electrically connected to a terminal device such as a reader (reading lead) is exposed on the card surface, and such an electrode is provided inside the IC card. And a contactless card stored in the card. Among these IC cards, the non-contact type IC card can effectively protect the electrodes (and thus the IC itself) from moisture, dust, etc., and the electrodes are not exposed on the card surface. Demand is gradually expanding for reasons such as being unaffected by the effects of the product and having an excellent appearance.
[0003]
The non-contact type IC card incorporates a coil for receiving a magnetic force from the terminal device side and inducing a current by electromagnetic induction when inserted into the card slot of the terminal device. An electronic component such as an IC chip is driven by the generated current. As this kind of non-contact type IC card, for example, there is one described in Japanese Patent Laid-Open No. 4-28697. That is, in Japanese Patent Laid-Open No. 4-286597, a coil, a semiconductor chip, and the like arranged and mounted on a circuit board are connected to each other through a wiring path, and the coil, the semiconductor chip, etc. are formed in an opening formed in a structural member. A personal data card is described in which the upper surface of the circuit board and the lower surface of the structural member are bonded together while the label sheet is bonded to each of the lower surface of the circuit board and the upper surface of the structural member.
[0004]
[Problems to be solved by the invention]
However, in the personal data card disclosed in Japanese Patent Laid-Open No. 4-286697, a normal winding coil is used as it is, and the two coil terminals of the winding coil are apparent from FIG. And electrically connected to the terminal pattern of the wiring path.
[0005]
By the way, since it is inconvenient in terms of portability when the card thickness is thicker than necessary, it is important that the IC card has a certain thickness or less. The height is relatively large. Therefore, in order to completely store the winding coil in the opening of the structural member, it is necessary to increase the thickness of the structural member. Thus, when the winding coil is used as described above, Since the thickness depends on the height of the winding coil, the thickness of the IC card cannot be reduced.
[0006]
In order to solve this problem, a method of forming a coil pattern connected to the wiring path on the circuit board instead of the winding coil can be considered. In this case, it is necessary to connect two coil terminals formed in the coil pattern to each other. For example, as one method, through holes are formed in each coil terminal, and each through hole is connected to the back surface of the circuit board. A method of connecting each coil terminal by forming a circuit pattern is conceivable. In this case, a double-sided circuit board is used as the circuit board.
[0007]
However, when the coil terminals of the coil pattern are connected to each other through the through holes and the circuit pattern as described above, the label sheet bonded to the lower surface of the circuit board is generally very thin. There is a problem that the through-hole, the circuit pattern itself, and the unevenness thereof are visually recognized from the lower surface (back surface) of the card and the appearance is deteriorated. In addition, since the double-sided circuit board that connects each coil terminal on the upper surface and the circuit pattern on the lower surface through the through holes is formed through many steps in manufacturing, the manufacturing cost increases. There's a problem. Further, in such a double-sided circuit board, an insulating resist layer is generally formed on both sides for protection of wiring paths and the like, and therefore the thickness of the IC card is increased by the amount of the insulating resist layer. It will be.
The present invention has been made to solve the above-mentioned conventional problems, and provides a non-contact type IC card with a built-in coil, which can reduce the thickness of the card at a low cost with good appearance. With the goal.
[0008]
[Means for Solving the Problems]
In order to achieve the above object, an IC card according to the present invention has a first flexible substrate on which an IC chip is mounted and a coil pattern having two coil terminals, and a first through hole that receives the IC chip. And provided with two second through holes corresponding to the respective coil terminals, a structural member joined on the first flexible substrate, and a third through hole corresponding to the respective second through holes. And a circuit pattern having a land pattern formed on the periphery of each third through-hole and a connection pattern for connecting each land pattern, and a second flexible substrate joined on the structural member, and the first flexible A pair of label sheets bonded to the lower surface of the substrate and the upper surface of the second flexible substrate, and the coil terminals are connected to the third through holes. By filling the conductive paste et second through hole has a configuration that is connected to each other via the respective land patterns and circuit patterns.
Here, the conductive paste is made of silver paste, and the silver paste is filled into the second through hole from the third through hole via a dispenser.
[0009]
[Action]
The IC card according to the present invention having the above configuration includes a first flexible substrate, a structural member bonded onto the first flexible substrate, a second flexible substrate bonded onto the structural member, and a lower surface of the first flexible substrate. It is comprised from a pair of label sheet joined to the upper surface of the 2nd flexible substrate. In such an IC card, the IC chip mounted on the first flexible substrate is received in the first through hole of the structural member, and the two coil terminals of the coil pattern formed on the first flexible substrate are By filling a silver paste as a conductive paste from a third through-hole provided in the second flexible substrate into a second through-hole through a dispenser, the peripheral edge of each third through-hole in the second flexible substrate Are connected to each other via a circuit pattern having a land pattern formed on each other and a connection pattern for connecting the land patterns.
[0010]
Thus, in the IC card according to the present invention, when the two coil terminals of the coil pattern are connected, the circuit pattern of the second flexible substrate is used inside the IC card without using a double-sided substrate as the first flexible substrate. Through the connection, the through-hole, the circuit pattern itself, and its unevenness are not visually recognized from the label sheet bonded to the lower surface of the first flexible substrate, and therefore the appearance of the IC card is good. It will be something. In addition, since the double-sided substrate on which the insulating resist layer is formed is not used, the cost of the IC card can be kept low, and the thickness of the IC card can be reduced.
[0011]
【Example】
Hereinafter, an IC card according to the present invention will be described in detail with reference to the drawings based on an embodiment embodying the present invention. First, the overall configuration of the IC card will be described with reference to FIG. FIG. 1 is an exploded perspective view of an IC card.
In FIG. 1, an IC card 1 is basically bonded to a first flexible substrate 2, a structural member 3 bonded to the first flexible substrate 2 via an adhesive, and an upper surface of the structural member 3 via an adhesive. The second flexible substrate 4, the lower label sheet 5 bonded to the lower surface of the first flexible substrate 2 via an adhesive, and the upper label sheet 6 bonded to the upper surface of the second flexible substrate 4 via an adhesive. , Have a five-layer structure stacked on each other.
[0012]
Here, the first flexible substrate 2 is made of a substantially rectangular polyester film (trade name “Lumirror”, thickness 125 μm), and a predetermined circuit pattern 7 is formed on the upper surface thereof. The circuit pattern 7 is provided with a coil pattern 8, and the coil pattern 8 has two coil terminals 9 and 10. This coil pattern 8 induces a current through an electromagnetic induction action based on receiving a magnetic force from the terminal device side when the IC card 1 is inserted into a card slot of the terminal device. The current induced in the coil pattern 8 is charged to the capacitor 11 and used to drive each IC chip 12. In FIG. 1, each capacitor 11 and IC chip 12 are shown in a resin-sealed state.
[0013]
The circuit pattern 7 is connected to a pair of transmission lands 13 and 13 and a pair of reception lands 14 and 14. Each transmission-side land 13 functions as a transmission antenna for transmitting data that has been subjected to computation and the like via each IC chip 12 to the terminal device side, and each reception-side land 14 is connected to the terminal device side. It acts as a receiving antenna for receiving the data calculated in step. Data received from the terminal device side via each receiving-side land 14 is stored in each IC chip 12.
Each capacitor 11 connected to the circuit pattern 7 is charged by a current induced through the coil pattern 8, and each IC chip 12 is driven through the charged electric energy. Each IC chip 12 calculates and stores various data.
[0014]
The structural member 3 is formed from a substantially rectangular polyester film (thickness: 350 μm), similar to the first flexible substrate 2. When the structural member 3 is joined to the first flexible substrate 2, The through hole 15 that houses the two capacitors 11, the through holes 16 and 17 that house the IC chips 12, the through hole 18 that corresponds to one coil terminal 9 in the coil pattern 8, and the other coil terminal A through-hole 19 corresponding to 10 is formed.
[0015]
The second flexible substrate 4 is formed of a substantially rectangular polyester film (thickness: 125 μm), similar to the first flexible substrate 2 and the structural member 3, and the second flexible substrate 4 includes the structural member 3. The through-holes 20 to 22 corresponding to the through-holes 15 to 17 formed in the above and having the same size as the respective through-holes 15 are formed. Each of the through holes 20 to 22 is covered with a cover sheet 28 made of a cloth (prepreg) partially cured and impregnated with an epoxy resin on the B stage. The cover sheet 28 is for protecting each capacitor 11 and the IC chip 12.
[0016]
The second flexible substrate 4 is formed with through holes 23 and 24 that correspond to the respective through holes 18 and 19 formed in the structural member 3 and are smaller than the respective through holes 18 and the like. Further, on the lower surface of the second flexible substrate 4, a land pattern 25 is provided at the periphery of the through hole 23, and a land pattern 26 is provided at the periphery of the through hole 24. A connection pattern is provided between the land patterns 25 and 26. 27 are connected to each other. Here, from each through hole 24, 25, as will be described later, a silver paste P is filled into each through hole 18, 19 of the structural member 3 via a dispenser D, and the filled silver paste P is: Filled in the through hole 18 connects the coil terminal 9 of the coil pattern 8 and the land pattern 25, and fills in the through hole 19 to connect the coil terminal 10 and the land pattern 26. Thereby, the coil terminals 9 and 10 of the coil pattern 8 are connected to each other via the connection pattern 27.
[0017]
Each of the label sheets 5 and 6 is made of a polyvinyl chloride sheet (thickness 25 μm). The label sheet 5 is bonded to the lower surface of the first flexible substrate 2 and the label sheet 6 is bonded to the upper surface of the second flexible substrate 4. It is joined through the agent.
[0018]
Next, a manufacturing method for manufacturing the IC card 1 configured as described above will be described with reference to FIGS. FIG. 2 is a cross-sectional view showing a state where the silver paste P is filled into the through holes 18 and 19 of the structural member 3 from the through holes 23 and 24 of the second flexible substrate 4.
In order to manufacture the IC card 1, first, the first flexible substrate 2, the structural member 3, which has a width and length slightly larger than those of the six pieces of the IC card 1 arranged (2 rows × 3 columns), A second flexible substrate 4 and a pair of label sheets 5 and 6 are prepared.
[0019]
At this time, on the first flexible substrate 2, the circuit pattern 7, the coil pattern 8 including the coil terminals 9, 10, the transmitting lands 13, the receiving lands 14, etc. are formed for each piece of the IC card 1. Has been. In order to create the first flexible substrate 2, a copper foil is bonded to a polyester film via an adhesive, and then a circuit pattern 7, a coil is used for each piece of the IC card 1 using a known etching process. A pattern 8, each transmission-side land 13, each reception-side land 14, each capacitor 11, and an IC chip 12 mounting land are formed.
[0020]
Similarly, in the structural member 3, for each piece of the IC card 1, a through hole 15 for storing each capacitor 11, through holes 16 and 17 for storing each IC chip 12, and coil terminals 9, 10 are provided. Through holes 18 and 19 are formed for exposure, and a predetermined amount of an ester-based thermoplastic adhesive is applied to both surfaces of the structural member 3. Further, similarly, in the second flexible substrate 4, for each piece of the IC card 1, the through holes 20 to 22 (corresponding to the through holes 15 to 17) and the through holes 23 and 24 (through holes) 18 and 19), and the land patterns 25 and 26 and the land patterns 25 are formed at the periphery of the through holes 23 and 24 on one surface (the lower surface in FIG. 1) of the second flexible substrate 4. , 26 are formed. The land patterns 25 and 26 and the connection pattern 27 are formed by applying a known etching process to each piece of the IC card 1 after bonding a copper foil to a polyester film via an adhesive. Is done.
[0021]
In this embodiment, in order to improve the production efficiency, the first flexible substrate 2 or the like corresponding to several pieces (6 pieces) of the final product is used. Of course, it is also possible to use one divided into two.
After the lower surface side of the structural member 3 is superimposed on the upper surface side of the first flexible substrate 2 prepared as described above, and further, the lower surface side of the second flexible substrate 4 is superimposed on the upper surface side of the structural member 3. After being subjected to hot press treatment (80 ° C., 40 kgf / cm ² ) for about 10 minutes, cooling is performed to obtain a laminate. Thereby, a laminate having a three-layer structure including the first flexible substrate 2, the structural member 3, and the second flexible substrate 4 is obtained.
[0022]
Next, for each piece of the IC card 1, each capacitor 11 is mounted on the mounting land of each capacitor 11 exposed in the through holes 15 and 20 in accordance with a conventional method. Similarly, each IC chip 12 is mounted on the mounting land of each IC chip 12 exposed in each of the through holes 16 and 21 and the through holes 17 and 22 according to a conventional method, and wire bonding or the like is performed. Processing is performed.
[0023]
Thereafter, each concave portion constituted by each of the through holes 15 to 17 and the through holes 20 to 22 is filled with a slurry made of ferrite particles and a soft epoxy resin, so that the capacitors 11 and the IC chip 12 are sealed with resin. Do. In addition, it may replace with the said slurry and you may fill with the epoxy resin whose hardness becomes higher than the polyester resin which comprises the structural member 3 after hardening.
[0024]
Subsequently, after the laminated body subjected to the above processing is positioned and arranged in the silver paste filling device, each piece of the IC card 1 is supplied with the silver paste P via the dispenser D as shown in FIG. The through holes 18 and 19 of the structural member 3 are filled from 23 and 24. Thus, the silver paste P filled in the through hole 23 comes into contact with the coil terminal 9 in the first flexible substrate 2 and the land pattern 25 at the periphery of the through hole 23, and the coil terminal 9 and the land pattern are formed. Connect to each other. Similarly, the silver paste P filled in the through hole 24 comes into contact with the coil terminal 10 in the first flexible substrate 2 and the land pattern 26 at the periphery of the through hole 24, and the coil terminal 10 and the land pattern 26. And connect to each other. Since the land patterns 25 and 26 are connected to each other through the connection pattern 27, the coil terminals 9 and 10 in the coil pattern 8 are connected to each other.
[0025]
As described above, in the IC card 1 according to the present embodiment, when the two coil terminals 9 and 10 of the coil pattern 8 are connected, the second flexible substrate 4 is used without using the double-sided substrate as the first flexible substrate 2. By filling the through holes 18 and 19 of the structural member 3 from the through holes 23 and 24 with the silver paste P, the land patterns 25 and 26 and the connection patterns 27 of the second flexible substrate 4 are formed inside the IC card 1. Therefore, the through-hole, the circuit pattern itself, and the unevenness thereof are not visually recognized from the label sheet 5 bonded to the lower surface of the first flexible substrate 2. Therefore, the appearance of the IC card 1 is good. Further, since the double-sided substrate on which the insulating resist layer is formed is not used, the cost of the IC card 1 can be kept low, and the thickness of the IC card 1 can be reduced.
[0026]
After connecting the coil terminals 9 and 10 in the coil pattern 8 as described above, the cover sheet 28 is disposed at a predetermined location surrounding the through holes 20 to 22. Thereafter, a predetermined amount of adhesive is applied to the upper surface of the lower label sheet 5 and disposed on the lower surface side of the first flexible substrate 2, and a predetermined amount of adhesive is applied to the lower surface of the upper label sheet 6 to form the second flexible sheet. It is arranged on the upper surface side of the substrate 4. And after performing a hot press process (150 degreeC, 40 kgf / cm < ² >) for about 10 minutes, it cools.
[0027]
Next, on the surface of each of the label sheets 5 and 6, for each portion corresponding to each piece of the IC card 1, printing of desired characters, numbers (for example, “bank name” when used as a cash card) and the like, Punching is performed to create an IC card board including 6 pieces of IC cards 1. Then, by cutting out this IC card plate for each piece according to a conventional method, the IC card 1 according to the present embodiment can be obtained as shown in FIG. FIG. 3 is a cross-sectional view showing the main part of the IC card 1.
[0028]
As described in detail above, in the IC card 1 according to this embodiment, when connecting the two coil terminals 9 and 10 of the coil pattern 8 formed on the first flexible substrate 2, a double-sided substrate is used as the first flexible substrate 2. Without use, the second flexible substrate 4 is filled inside the IC card 1 by filling the through holes 18 and 19 of the structural member 3 with the silver paste P from the through holes 23 and 24 of the second flexible substrate 4. Since the land patterns 25 and 26 and the connection pattern 27 are used for connection, the through-hole, the circuit pattern itself, and its unevenness can be visually recognized from the label sheet 5 bonded to the lower surface of the first flexible substrate 2. The IC card 1 having a better appearance can be obtained.
[0029]
In addition, since the double-sided substrate on which the insulating resist layer is formed is not used, the cost of the IC card 1 can be kept low, and the thickness of the IC card 1 can be reduced. The present invention is not limited to the above-described embodiments, and various improvements and modifications can be made without departing from the scope of the present invention.
[0030]
【The invention's effect】
As described above, the present invention can provide a non-contact IC card with a built-in coil that can reduce the thickness of the card at a low cost and can be thinned.
[Brief description of the drawings]
FIG. 1 is an exploded perspective view of an IC card.
FIG. 2 is a cross-sectional view showing a state in which a silver paste is filled into each through hole of a structural member from each through hole of a second flexible substrate.
3 is a cross-sectional view showing the main part of the IC card 1. FIG.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 IC card 2 1st flexible substrate 3 Structural member 4 2nd flexible substrate 5, 6 Label sheet 7 Circuit pattern 8 Coil pattern 9, 10 Coil terminal 11 Capacitor 12 IC chip 13 Transmission side land 14 Reception side land 15-24 Through-hole 25, 26 Land pattern 27 Connection pattern D Dispenser P Silver paste

Claims (2)

A first flexible board on which an IC chip is mounted and a coil pattern having two coil terminals is formed;
A first through-hole for receiving the IC chip and two second through-holes corresponding to the coil terminals, and a structural member joined on the first flexible substrate;
A third through hole is provided corresponding to each second through hole, and a circuit pattern having a land pattern formed on the periphery of each third through hole and a connection pattern for connecting each land pattern is provided, and the structure A second flexible substrate joined on the member;
A pair of label sheets bonded to the lower surface of the first flexible substrate and the upper surface of the second flexible substrate,
The coil terminals are connected to each other through the land patterns and circuit patterns by filling the second through holes with conductive paste from the third through holes. card. 2. The IC card according to claim 1, wherein the conductive paste is made of a silver paste, and the silver paste is filled into the second through hole from the third through hole through a dispenser.

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