KR101070303B1 - Combi card producting method and the combi card which is manufactured by using this - Google Patents

Abstract

The present invention relates to a combi card manufacturing method and a combi card manufactured using the same, the method comprises the steps of forming an antenna having a predetermined pattern with the antenna terminal portion in the sheet using a thermocompression bonding process; A step of forming a recess in the sheet so that the antenna terminal is exposed through a milling process; Applying an adhesive to the lead frame except for the COB terminal; And a step of allowing the COB terminal and the antenna terminal portion to be connected to the wire by a laser and inserting and bonding the COB terminal to the recess. Combi card of the present invention is a plurality of stacked sheets; An antenna having a predetermined pattern and mounted between the sheets; An antenna terminal unit connected to the antenna in a state mounted between the sheets; A COB terminal mounted on the sheet to overlap with the antenna terminal portion; And a wire connecting the COB terminal and the antenna terminal part.

Combi card, seat, antenna, antenna terminal, COB terminal, wire

Description

Combi card producting method and the combi card which is manufactured by using this}

The present invention relates to a combi card manufacturing method and a combi card manufactured using the same, and more particularly, by separately allowing the antenna terminal portion and the COB terminal to be interconnected by laser welding can not only prevent the antenna coil from disconnection. The present invention relates to a combination card manufacturing method and a combination card manufactured using the same, which enables to form a good connection state between an antenna terminal portion and a COB terminal.

In general, cards have long been used as data carriers. Usually, cards record and transmit data visually as information or printed on one or both surfaces of the card. The cards may also function as magnetic data carriers in the form of magnetic cards. In magnetic cards, a magnetic strip is pressed at a specific location on the card. The magnetic strip transmits the data readable by the magnetic card reader. Magnetic cards can be used for train tickets, bank cards, and the like. However, these magnetic cards have the disadvantage of having a small amount of data that can be transferred or recorded by the magnetic strip. Moreover, magnetic cards can only be overwritten relatively few times and are easily destroyed. Magnetic cards are susceptible to magnetic fields around them and even data stored therein can be lost.

As an improvement on the conventional data-carrier card described above, "smart card" or "IC card" has been provided. These cards have integrated circuits (ICs) for data storage. In current technology, integrated circuits (ICs) can store more than 30k bytes of data and overwrite and read 100,000 times. Because ICs can contain both data and programs, smart cards can be used remotely from computer terminals. IC cards are used as telephone cards or credit cards. These cards sometimes also include a magnetic strip, thus providing two interfaces.

IC cards can generally be classified into contact cards and contact-less cards. In the case of a contact card, the major surface of at least one IC card with a read / write interface is exposed to the external environment. In use, the read / write interface of the IC card is in direct physical contact with the read / write head of the computer terminal or processor, thereby causing data to be written to or read from the IC in the card. Can be. On the other hand, a contactless card is provided with a coil of copper wire, which is connected to the IC at or near both ends which are completely embedded in the IC. The copper wire coil serves as an antenna for transmitting and receiving radio frequency signals. The IC is then connected to an external system, for example a computer system, by radio frequency (RF). In this case, the IC does not need to be in direct contact with any lead / light head of the external computer system.

If a contact IC card is used frequently, for example once or twice a day or more, the IC contained therein will be easily damaged. In certain circumstances, the use of contact cards may waste more time. For example, in the case of expressway toll payment, when using a contact card, all cars passing through the toll gate must stop for payment processing. Therefore, contactless cards occur relatively frequently but are suitable for use in relatively small payment transactions.

Contactless IC cards may be classified into high frequency contactless IC cards and low frequency contactless IC cards. The operating frequency of the high frequency contactless IC card (also called high frequency card) is 13.56 MHz, while the operating frequency of the low frequency noncontact IC card (or low frequency card) is 125 kHz. The high frequency card is provided with 4 to 5 rounds of copper wire coils, and their working distance is within about 10 cm.

The high frequency card is very reliable because it is unlikely to affect or be affected by the operation of another nearby high frequency card. In the case of a low frequency card, 250 to 300 round copper wire coils are provided. While the manufacture of low frequency cards is rather complicated and difficult to automate, its main advantage is that its operating distance is up to 3 m.

High frequency cards are usually used for personal purposes, such as when traveling by train or boarding a bus. Low frequency cards can be used for expressway toll payments because radio frequency signals can be transmitted over long distances and different vehicles are relatively easy to distinguish.

In the case of a high frequency card, there are three ways of providing a coil in the card: printing, etching, and embedding. In the printing method, a plurality of coils are formed by printing electroconductive ink on a core sheet. This method requires a fast and relatively inexpensive device. However, this method has the disadvantage that the printed "wire" is easily damaged. In addition, the electrical conductivity is not constant because it depends on the mixing between some electrically conductive metal powder and the ink. The printed circuit is so thin that it cannot pass the bending test required under relevant international standards. Moreover, in the printing method, adjacent round wires cannot be too close together, so that the efficiency of radio frequency transmission is significantly reduced. Because of the various problems described above, this method is rarely used at present.

Looking at the etching method, this method is similar to that used in the production of circuit boards. However, because adjacent rounds of wire cannot be too close to each other, the efficiency of radio frequency transmission is poor. In addition, problems arise that pollute the surrounding environment during production. The card thus produced cannot pass the bending test. Therefore this method is rarely used.

In the case of the embedded method, this method is very versatile and adjacent rounds of two wires can ultimately be in contact with each other, significantly improving radio frequency transmission efficiency. This method can be automated without adversely affecting the surrounding environment. Cards produced by this method can also pass bending tests.

Recently, in addition to contact and contactless cards, a kind of card incorporating the functions of a contact card and a contactless card has been proposed. Such a card is called a combination card or dual-interface IC card. For convenience, the term "combi card" is used below.

Although integrated circuits (ICs) are built into the combi card, as in the case of a contact card, the IC's read / write head in an external system can be in physical contact with the IC to read data from or write data to the IC. The main surface is exposed. On the other hand, as in the case of a contactless card, the IC of the combi card is electrically connected to an antenna coil embedded in the card, so that the IC can be connected to an external system by radio frequency transmission, and thus data is read from the IC or the IC Can be used in This allows the combination card to be used in more diverse environments.

In existing methods of manufacturing combi cards, the IC is fixed to the antenna coil by a conductive adhesive. The disadvantage of this method is that the physical connection between the antenna coil and the IC is not strong enough, resulting in the inability to meet the requirements of ISO-7816-1 and ISO10536-1.

In order to make up for the shortcomings of such combination cards, Patent Publication No. 2002-62198 discloses a method for manufacturing a dual-interface IC card and a card manufactured by the method. The antenna coil is removed from the seat, connecting the integrated circuit to the antenna coil, and then remounted and fixed by soldering or thermal compression bonding.

However, when the antenna coil is removed and connected to the integrated circuit and then remounted, the antenna coil may not be correctly mounted when the antenna coil is removed, causing disconnection.

In addition, there was a problem that the antenna coil is disconnected in the process of removing the antenna coil. That is, as the disconnection of the antenna coil occurs frequently by the method of directly connecting the antenna coil to the integrated circuit, there is a disadvantage that the cost of the cost increases due to the delay of the work process.

The present invention has been made to solve the above problems, an object of the present invention is to prevent the antenna coil is disconnected by allowing the antenna terminal portion and the COB terminal provided separately can be interconnected to the sheet by laser welding. Rather, the present invention provides a combination card manufacturing method and a combination card manufactured using the same, which enables to form a good connection state between an antenna terminal portion and a COB terminal.

The present invention has the following structure in order to achieve the above object.

In the combination card manufacturing method of the present invention, the combination card manufacturing method for connecting the COB terminal and the antenna by a welding method, the step of forming an antenna having a predetermined pattern and the antenna terminal portion on the sheet using a thermocompression bonding process; A step of forming a recess in the sheet so that the antenna terminal is exposed through a milling process; Applying an adhesive to the lead frame except for the COB terminal; And a step of allowing the COB terminal and the antenna terminal unit to be connected to the wire terminal by a laser and inserting and bonding the COB terminal to the recess.

On the other hand, the combination card of the present invention, the combination card formed by welding the COB terminal and the antenna, a plurality of laminated sheets; An antenna having a predetermined pattern and mounted between the sheets; An antenna terminal unit connected to the antenna in a state mounted between the sheets; A COB terminal mounted on the sheet to overlap with the antenna terminal portion; And a wire connecting the COB terminal and the antenna terminal part.

The wire also allows the antenna terminal portion and the COB terminal to be connected by laser welding.

And it is preferable that the sheet is fused by a thermal compression method.

According to the present invention, it is possible to prevent the antenna coil from being disconnected by allowing the separately provided antenna terminal portion and the COB terminal to be interconnected by laser welding, and to form a good connection between the antenna terminal portion and the COB terminal. It works.

In addition, according to the present invention, by connecting to the COB terminal by using a separate wire and antenna terminal portion can secure the connection state of the COB terminal and the antenna can shorten the work process time and increase the process yield, the expected effect of reducing the cost There is.

Hereinafter, preferred embodiments of the present invention will be described in more detail with reference to the accompanying drawings. The embodiments of the present invention may be modified in various forms, and the scope of the present invention should not be construed as being limited to the embodiments described below. These embodiments are provided to explain in detail the present invention to those skilled in the art. Accordingly, the shape of each element shown in the drawings may be exaggerated to emphasize a more clear description.

1 is a perspective view showing a combination card of the present invention, Figures 2 to 5 is a process chart showing a combination card manufacturing method of the present invention.

As shown in FIG. 1, the combination card 100 is laminated with a plurality of sheets 110 having a predetermined size and bonded to each other. An antenna 121 having a predetermined pattern is mounted inside the sheet 110. . The antenna 121 is typically a thermoplastic material (for example, Plexiglass, Polyvinyl Chloride, Polyropylene, and Acrylonitrile Butadiene-styrene). Or a heat resistant material (eg, epoxy-fiberglass) coated with a thin layer of semi-cured thermosetting resin adhesive (eg, approximately the radius of the antenna).

In addition, it is known that the sheet 110 may form a filler sheet, a protective sheet, a graphic sheet, an outer transparent sheet, etc. according to the purpose of the product card.

In addition, the antenna 121 is in contact with the antenna terminal 120 mounted on the seat 110, the antenna terminal 120 is located above the antenna and the antenna terminal 120 is exposed to the outside The bottom surface is provided with a COB terminal 130 connected to the antenna terminal 120 by a wire. As described above, the COB terminal 130 constitutes a constant circuit so that data can be stored and stored in the mounted circuit. Here, the antenna terminal 120 has a through hole formed therein.

Combi card 100 of the present invention as described above is manufactured by the method as shown in Figs.

First, as shown in FIG. 2, after stacking a plurality of sheets 110, the antenna terminal 120 and the antenna 121 are positioned between the sheets 110. In this state, the sheet, the antenna terminal portion, and the antenna are fused using a thermocompression bonding process.

Next, as shown in FIG. 3, the upper surface of the sheet 110 is processed using a milling process to form the recess 111 to expose the upper surface of the antenna terminal 120. At this time, it is preferable that the through-hole 122 formed in the center portion of the antenna terminal 120 can be opened like the recess 111.

Next, as shown in FIG. 4, the COB terminal 130 is positioned on the recess 111 having the upper portion of the sheet 110 open. At this time, the bottom of the COB terminal 130 has a stepped shape, and an adhesive 131 is coated on the stepped lead frame (not shown) on the bottom. The adhesive 131 is preferably made of an insulating material.

The COB terminal 130 and the antenna terminal 120 are connected using the wire 140. In this case, the wire 140 is surrounded by an enamel coating material so that the wire is exposed to the enamel covering material by using a laser, and then the exposed wire is contacted to each of the COB terminal and the antenna terminal part by laser welding.

Next, as shown in FIG. 5, the COB terminal 120 contacted with the antenna terminal 120 by a wire is inserted into the recess 111 so that the stepped portion of the COB terminal 120 is inserted into the through hole of the antenna terminal. The adhesive 131 is inserted and applied to the bottom surface of the COB terminal to adhere to the top surface of the antenna terminal. In this state, the COB terminal and the antenna terminal portion in the bonded state are thermally compressed to be fixed in the sheet.

In this way, when the COB terminal embedded in the card is connected to the antenna by using a separate wire and the antenna terminal portion, it is possible to prevent an antenna disconnection problem that may occur when the COB terminal and the antenna are connected, and the antenna is mounted in the seat. Combi card can be manufactured in a state so that the antenna position can be accurately set and manufactured.

In addition, the antenna integrated with the seat enables the use of various COB terminals by replacing COB terminals.

The present invention is not limited by the embodiments described above, and various changes and modifications can be made by those skilled in the art, which are included in the spirit and scope of the present invention as defined in the appended claims.

1 is a perspective view showing a combination card of the present invention.

2 to 5 are process charts showing the combination card manufacturing method of the present invention.

DESCRIPTION OF THE REFERENCE SYMBOLS

100: combination card 110: sheet

111: groove portion 120: antenna terminal portion

121: antenna 122: through-hole

130: COB terminal 131: adhesive

140: wire

Claims (5)

In the combi card manufacturing method for connecting a chip on board (COB) terminal and the antenna by a welding method, A step of forming an antenna having a predetermined pattern on the sheet with the antenna terminal portion by a thermocompression bonding process; A step of forming a recess in the sheet so that the antenna terminal is exposed through a milling process; Applying an adhesive to the lead frame except for the COB terminal; And And a step of allowing the COB terminal and the antenna terminal portion to be connected to each other by laser welding and inserting and bonding the COB terminal to the recess. The antenna is coated with Plexiglass, Polyvinyl chlorde, Polyropylene and Acrylonitrile Butadiene-styrene, or a semi-hardened thermosetting adhesive layer Combi card manufacturing method characterized in that the production of a heat-resistant material. delete In the combination card formed by welding a COB terminal and an antenna, A plurality of laminated sheets; An antenna having a predetermined pattern and mounted between the sheets; An antenna terminal unit connected to the antenna in a state mounted between the sheets; A COB terminal mounted on the sheet to overlap with the antenna terminal portion; And And a wire connecting the COB terminal and the antenna terminal part. The wire allows the antenna terminal portion and the COB terminal to be connected by laser welding, The antenna is coated with Plexiglass, Polyvinyl chlorde, Polyropylene and Acrylonitrile Butadiene-styrene, or a semi-hardened thermosetting adhesive layer Combi card, characterized in that made of a heat-resistant material. delete The method of claim 3, wherein Combi card, characterized in that the sheet is fused by a thermal compression method.

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