DE202023104660U1 - Bank card - Google Patents

Abstract

The bank card comprises two outer metal layers, a middle layer made of dielectric material with an antenna mounted thereon, the middle layer being connected to the outer metal layers by means of adhesive layers, each metal layer comprising an opening in the area of attachment of the antenna of the contactless interface and from A slot is formed on a side edge of the body up to the opening, the slot in the first metal layer being formed offset from the slot on the second metal layer, the second metal layer being shortened in comparison to the first by the width of a magnetic strip, which is on a plastic insert a width equal to the width of the magnetic strip is applied, the plastic insert being attached to the middle layer via an adhesive layer, into which openings and slots of the outer metal layers inserts made of dielectric material are installed, one of which has a slot in which a chip is attached which is connected to the card's antenna.

Description

The utility model refers to bank cards that are formed from layers of different materials and their combinations (metal, plastic, wood veneer, paper, etc.) and include a contact and a contactless interface. In bodies of such cards, an area must be provided for the placement of an antenna for the contactless interface, and in order to ensure the functioning of the antenna, the perimeter of this area must be interrupted to prevent the formation of eddy currents.

The following technical solutions are known from the prior art.

A hybrid metal chip card is known ( EP patent 3 748 543 , published December 9, 2020), comprising a metal card body having a slot, allowing the card body to function as a coupling frame; one or more recesses on a front and/or a back of the card; and a non-conductive filler material that fills the recess(s).

Also known is a metal chip card configured to receive power from a contactless reader (U.S. Patent 11354560 , published June 7, 2022), comprising a metal body having a first edge and a second edge opposite the first edge, the metal body including a slot extending to an outer edge of the metal body; at least one recess on at least one of the first surface and the second surface of the metal body; and at least one filler portion disposed at least partially in at least one recess, the filler portion comprising a substantially non-conductive material.

The technical problem is that the continuous slot makes the card construction unstable at this point and, furthermore, since the slot is continuous, difficulties arise in its subsequent filling, dielectric materials (plastics, epoxies, etc.) usually being used as filler material. Also, in designs of this type of cards, it is difficult to attach a magnetic strip, which is currently still quite actively used in some countries.

The closest state of the art to the claimed solution is a chip card ( US 9836684 , published on December 5, 2017), comprising a metal card body having an opening for receiving a chip module, a slot extending from an edge of the card body to the opening, the card body thinning in an area including the slot is, so that the back of the metal card body is recessed, a carrier insert arranged in the recess, which includes the slot and reinforces the card body in the area of the slot, and a chip module cover which is inserted into the module opening in the back of the card body, wherein the thinned area extends to the area of the transponder chip module, including the area surrounding the opening, the carrier insert includes a module opening and a second slot extending from an edge of the carrier insert to the module opening, the insert in the card so is aligned so that the second slot is arranged in a central area of the card body. The front metal layer is shielded from the underlying metal layers by a protective layer. An adhesive layer is arranged between the first and second metal layers, which in a special embodiment is a plastic film.

The known solution solves the problem of maintaining the strength of the metal body at the points of attachment of the double interface with the antenna, but no solution is provided to the problem of attaching a magnetic strip while maintaining the thickness of the body and its strength at the point of attachment of the magnetic strip, taking into account the position of the inserts.

The technical result of the claimed utility model is the possibility of installing within the card body a contact and a contactless interface and a magnetic strip while maintaining the strength of the card in the places where they are installed and the thickness of the card.

The claimed technical result is achieved by the construction of a bank card comprising two outer metal layers, a middle layer of dielectric material with an antenna mounted thereon, the middle layer being connected to the outer metal layers by means of adhesive layers, each metal layer having an opening in the area the attachment of the antenna of the contactless interface and a slot is formed from a side edge of the body to the opening, the slot in the first metal layer being offset from the slot on the second metal layer, the second metal layer compared to the first by the width of the Magnetic strip is shortened, which is applied to a plastic insert with a width equal to the width of the magnetic strip, with the plastic insert on the middle layer an adhesive layer is attached, into which openings and slots of the outer metal layers are installed inserts of dielectric material, one of which has a slot in which a chip is mounted which is connected to the antenna of the card.

In a special embodiment, the slot in the first metal layer is offset by 90 degrees from the slot on the second metal layer.

In a special embodiment, the slot in the first metal layer is offset by 180 degrees from the slot on the second metal layer.

In a special embodiment, the inserts are made of PVC plastic, PLA, hard glass fabric.

In a particular embodiment, the outer layers are made of stainless steel or a titanium alloy or of gold, or silver or platinum.

In a special embodiment, the middle layer is made of hard glass fabric, hard fabric, hard paper, ceramic, polycarbonate, PVC plastic.

In a special embodiment, the middle layer is made of a film material (hard glass fabric, hard paper, polyimide) on which an antenna is made, which is formed by printing processes.

• 1 ist eine allgemeine Ansicht der Schichten des Kartenkörpers.
• 2 ist eine erweiterte Ansicht der Metallschichten der Karte.
• 3 ist eine schematische Darstellung des Einbaus eines Magnetstreifens.
• 4 ist eine schematische Darstellung des Einbaus eines Magnetstreifens.
• 5 ist eine schematische Darstellung der Karte für den Fall der Anordnung des Chips im Bereich der Antenne.
• 6 ist eine schematische Darstellung des Einbaus des Chips in die Karte für den Fall der Anordnung des Chips im Bereich der Antenne.
• 7 ist eine schematische Darstellung der Karte für den Fall der Anordnung des Chips außerhalb des Bereichs der Antenne.
• 8 ist eine schematische Darstellung des Einbaus des Chips in die Karte für den Fall der Anordnung des Chips im Bereich der Antenne.

The solution is explained below with reference to the figures showing the following.

• 1 is a general view of the layers of the map body.
• 2 is an expanded view of the card's metal layers.
• 3 is a schematic representation of the installation of a magnetic strip.
• 4 is a schematic representation of the installation of a magnetic strip.
• 5 is a schematic representation of the card if the chip is arranged in the area of the antenna.
• 6 is a schematic representation of the installation of the chip in the card if the chip is arranged in the area of the antenna.
• 7 is a schematic representation of the card in the case of placing the chip outside the area of the antenna.
• 8th is a schematic representation of the installation of the chip in the card if the chip is arranged in the area of the antenna.

The bank card according to the utility model comprises two outer metal layers (1) and (5), a middle layer (3) made of a thin, relatively solid dielectric material, for example hard glass fabric, hard fabric, hard paper, ceramic, polycarbonate, PVC plastic. The middle layer is connected to the outer metal layers by means of adhesive layers (2) and (4), making the entire construction irremovable. Openings (6) in the outer metal layers are provided for the arrangement of the antenna of the contactless interface. Slots (7) and (8) in the outer metal layers (1) and (5) from the side edge of the body to the opening are provided to break the circuit and avoid eddy currents affecting the operation of the contactless interface. The slots on the top and bottom layers are clearly offset, e.g. B. by 90 degrees, with the maximum offset value being 180 degrees, as in 1 shown. As a result, the strength of the structure in the area of the slot (7) of the upper metallic outer layer (1) is ensured by the integrity at this point of the other layers (3) and (5), and the strength of the structure in the area of the slot (8) the lower metallic outer layer (5) is guaranteed by the integrity at this point of the layers (1) and (3). Thus, the presence of the dielectric layer (3) between the metal layers and the slots (7), (8) in each of the layers (1), (5) creates an open circuit in which the antenna of the contactless interface will operate effectively. Schematically, the structure of such a construction can be expanded in 2 to be shown. This clearly shows that with such a construction we have two metallic interrupted circuits (6) that are not electrically connected to each other, since the layers (1) and (5) are connected via the dielectric layer (3).

The second metal layer (5), which serves as the back of the card, is shortened on the long side compared to the first by the width of the magnetic strip, which is applied to a plastic insert with a width equal to the width of the magnetic strip, with the plastic insert on the middle layer an adhesive layer is attached. 3 shows a card back design in which the magnetic stripe is spaced from the edge of the card, which is the most common embodiment. In this case, the metal layer (5) serving as the back of the card is cut into three parts and the middle part is replaced by a plastic insert (13) with a magnetic strip (14) applied to it. The total di The thickness of the plastic insert (13) and the magnetic strip (14) must be equal to the thickness of the metal layer (5). All of these parts are then attached to the dielectric layer of the card (3) via the adhesive layer (4). 4 shows an embodiment of the card back construction in which the magnetic strip is attached to the edge of the card. In such an embodiment, the metal layer (5) is shortened on the long side by the width of the magnetic strip, and a plastic insert (13) with a magnetic strip (14) applied to it is attached to the vacant area. As in the previous case, the total thickness of the plastic insert (13) and the magnetic strip (14) corresponds exactly to the thickness of the metal layer. The attachment of the metal layer and the magnetic strip to the card elements is completely identical to the previous embodiment. Another advantage achieved when using a magnetic strip is that the slot (7), which is required for the operation of the antenna on the back, can be moved to the area of the magnetic strip so that it is on the front side will not be visible on the card and the external appearance of the product will be improved accordingly.

A schematic representation of a card manufactured according to the proposed technology is shown in 5 shown. The front of the card is the outer metal layer (1) and the back of the card is the outer metal layer (5). The outer layers (1) and (5) may be formed of stainless steel or a titanium alloy or of gold or silver or platinum. An antenna (12) with contacts for connecting a chip (9) is arranged on the dielectric layer (3). The opening (6) on the front of the card is filled with an insert (10) made of radiolucent material. The insert (10) has a slot in which a chip (9) connected to the card's antenna is attached. The opening (6) on the back of the card is filled with an insert (11) made of radiolucent material. The inserts on one of the sides have a thin element extending beyond the boundaries of the insert, sized to correspond to the size of the slot in the front and back. When installing the inserts, these elements are inserted into the slots and make the slots invisible. The inserts can be made of PVC plastic, PLA, hard glass fabric and other dielectric materials. The adhesive layers arranged between layers (1) - (3) and (3) - (5) are in 5 not shown. 6 shows a schematic representation of the card when the area of the arrangement of the microprocessor is in the area of the arrangement of the antenna. In this case, the microprocessor is implanted in the following way. When producing the antenna (12), contact surfaces are formed in the area of the arrangement of the chip, which are made of densely arranged multiple conductors (if the antenna is made of wire), and solid contact surfaces if the antenna is made by printing processes. A receptacle (15) for the chip module (9) is created in the insert (10) on the front of the card. When forming the receptacle for the chip, the contact surfaces of the antenna are cleaned. The chip is implanted using a special implantation device in automatic mode. Either solder or anisotropic tape is used as the material that creates the electrical contact (16) between the antenna and the chip, with the anisotropic tape only conducting the current in one direction. If anisotropic tape is used, it also fulfills an adhesive function in addition to electrically conductive functions. In the event that the electrical contact is made using solder, the chip is attached to the card using thermoactivated adhesive tape (not shown in the schematic). A magnetic strip (14) is arranged on the back of the card and is glued to a plastic insert (13).

In the event that the area of installation of the microprocessor does not coincide with the area of arrangement of the antenna, the design of the card looks as shown 7 shown. The main difference is that extended conductors (18) are laid between the chip and the antenna. These conductors are formed using the same technology as the antenna itself, ie either with wire or by printing methods, and form a unit with the antenna (12). Considering that the extended conductors will be covered by the front metal layer (1), in order to avoid their damage or short circuit with the metal layer, a technological lowering (17) is made in the latter, which runs along the entire length of the conductors from the area of the assembly the antenna (6) extends to the area where the chip is arranged. The configuration, depth and width of the depression is selected to prevent damage to the ladder during final assembly of the product. A schematic representation of the installation of the chip in this embodiment is shown in 8th shown. A receptacle (15) for the chip is formed in the layers of the card. When forming the receptacle for the chip, the contact surfaces of the antenna (12) are cleaned. The chip is implanted using a special implantation device in automatic mode. Either solder or anisotropic tape is used as the material that creates the electrical contact between the antenna and the chip module (16), with the anisotropic tape only conducting the current in one direction. If anisotropic tape is used, it also fulfills electrically conductive functions Adhesive function. In the event that the electrical contact is made using solder, the chip is attached to the card using thermoactivated adhesive tape (not shown in the schematic). The schematic representation shows a depression (17) in the front layer (1), which prevents damage to the extended conductors (18).

QUOTES INCLUDED IN THE DESCRIPTION

This list of documents listed by the applicant was generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• EP 3748543 [0003]
• US 11354560 [0004]
• US 9836684 [0006]

Claims (1)

The bank card comprises two outer metal layers, a middle layer made of dielectric material with an antenna mounted thereon, the middle layer being connected to the outer metal layers by means of adhesive layers, each metal layer comprising an opening in the area of attachment of the antenna of the contactless interface and from A slot is formed on a side edge of the body up to the opening, the slot in the first metal layer being formed offset from the slot on the second metal layer, the second metal layer being shortened in comparison to the first by the width of a magnetic strip, which is on a plastic insert a width equal to the width of the magnetic strip is applied, the plastic insert being attached to the middle layer via an adhesive layer, into which openings and slots of the outer metal layers inserts made of dielectric material are installed, one of which has a slot in which a chip is attached which is connected to the card's antenna.

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