RU2818686C1 - Payment smart card with contactless interface and light-emitting diodes (versions) - Google Patents

Abstract

FIELD: physics.

SUBSTANCE: proposed invention relates to bank smart cards and contactless payment bank means. Contactless payment smart card with light-emitting diodes comprises a frame antenna, a contactless chip module, a middle sheet substrate, upper sheet substrate, lower sheet substrate, upper and lower sheets of lamination film, wherein sheet substrates and sheets of lamination film have front and back sides. Middle sheet substrate is a base for arranging light-emitting diodes, a contactless chip module and a frame antenna on it.

EFFECT: wider range of technical means aimed at creating a payment smart card with a contactless interface and light-emitting diodes.

10 cl, 3 dwg

Description

Technical field

A group of inventions relates to payment banking smart cards and contactless payment banking instruments operating using Near Field Communication (NFC) wireless data transmission technology. Smart card data is used to make contactless payments when paying for purchases, using public transport, when attending public events, authentication, information exchange and other purposes.

State of the art

Payment bank smart cards, both contactless payment and with a dual interface, are widely known from the state of the art, which allow the owner of a bank account to carry out transactions by exchanging information between the payment smart card and the reading device via a radio frequency channel, as well as by contact reading information from chip module, when the card is physically inserted into a reader, including an ATM.

As an example, we can cite the technical solution disclosed in the utility model patent RU 215746 U1, publ. 12/23/2022 (hereinafter referred to as D1). The known technical solution from D1 relates to a payment card with a dual interface and LEDs. The payment card contains a loop antenna formed by coils of conductive wire implanted in a plane into a sheet of plastic, a chip module with a dual interface connected to the loop antenna via inductive coupling or through direct connection due to a thermally activated layer applied to the reverse side of the chip module with a dual interface anisotropic adhesive, a loop antenna formed by turns of conductive wire connected to semiconductor LEDs implanted in a plane into a sheet of plastic, as well as sheets of plastic for the front and back sides of cards for printing graphic information (design) and text information on them, and sheets of lamination film for the front and back sides of cards, which serve as a protective coating for smart cards from external influences.

To pay with this card using the contact method using a dual chip module, part of the card is located inside the reader and, accordingly, hides the indication of the LEDs located in the edge zone, which is a disadvantage of this device. In addition, the D1 payment card has a complex design due to the presence of an additional layer of plastic to accommodate an additional loop antenna and complex technology for implanting a contact chip module to ensure electrical contact with the antenna.

Disclosure of the Invention

The technical results of the proposed group of inventions are:

- to simplify the design of a payment smart card with a contactless interface and LEDs while ensuring its functionality,

- to simplify the smart card assembly technology due to the absence of the need to provide a contact connection between the chip module and the payment terminal,

- increasing the usable area for placing design elements,

- eliminating factors affecting the overlap of the LED indication during operation (through the use of a contactless payment method).

- expanding the arsenal of technical means aimed at creating a payment smart card with a contactless interface and LEDs.

The declared technical results are achieved by each variant of the proposed technical solution, which are characterized by the following set of essential features.

A payment smart card with a contactless interface and LEDs according to the first embodiment, containing a loop antenna electrically connected to a contactless chip module, a middle sheet substrate, an upper sheet substrate, a lower sheet substrate, upper and lower sheets of lamination film, and sheet substrates and sheets lamination films have a front and back side, wherein the backing sheets and lamination film sheets are combined into a multilayer structure formed by joining the backing sheets and lamination film sheets so that the middle backing sheet is sandwiched between the top and bottom backing sheets, the top lamination film sheet having its backing side is connected to the front side of the upper sheet substrate, and the bottom sheet of the lamination film is connected with its reverse side to the front side of the lower sheet substrate, and the middle sheet substrate is the basis for placing on it LEDs, a contactless chip module, a loop antenna and an additional loop antenna, electrically connected to the LEDs, in turn, the loop antenna with the contactless chip module is placed in the plane of the middle sheet substrate on its reverse side, and on the front side of the middle sheet substrate there are LEDs and an additional antenna.

The LEDs are placed inside the area formed by the additional loop antenna contour, and the contactless chip module is placed inside the area formed by the loop antenna contour, and the minimum distance of the LEDs from the antennas is 10 mm.

The loop antenna and the additional loop antenna are formed by coils of conductive wire.

The second embodiment discloses a payment smart card with a contactless interface and LEDs, comprising a loop antenna electrically coupled to a contactless chip module, a middle sheet substrate, a top sheet substrate, a bottom sheet substrate, top and bottom lamination film sheets, wherein the sheet substrates and sheets lamination films have front and back sides, wherein the backing sheets and lamination film sheets are combined into a multilayer structure formed by joining the backing sheets and lamination film sheets so that the middle backing sheet is sandwiched between the top and bottom backing sheets, the top lamination film sheet being its back side connected to the front side of the upper sheet substrate, and the bottom sheet of the lamination film with its reverse side is connected to the front side of the lower sheet substrate, and the middle sheet substrate is the basis for placing on it LEDs, a contactless chip module, a loop antenna and an additional loop antenna electrically connected with LEDs, in turn, a loop antenna with a contactless chip module and an additional loop antenna with LEDs are placed in the plane of the middle sheet substrate on its front side.

The LEDs are placed inside the area formed by the contour of the additional loop antenna, and the contactless chip module is placed inside the area formed by the contour of the loop antenna, and the contour of the additional loop antenna is placed inside the area formed by the contour of the loop antenna and free from the placement of the contactless chip module.

The loop antenna and the additional loop antenna are formed by coils of conductive wire.

In a third embodiment, a payment smart card with a contactless interface and LEDs, comprising a loop antenna electrically coupled to a contactless chip module, a middle sheet substrate, a top sheet substrate, a bottom sheet substrate, top and bottom sheets of lamination film, wherein the sheet substrates and the lamination film sheets have a front and back side, the backing sheets and the lamination film sheets being combined into a multi-layer structure formed by joining the backing sheets and the lamination film sheets such that the middle backing sheet is sandwiched between the top and bottom backing sheets, the top lamination film sheet having its back side side is connected to the front side of the upper sheet substrate, and the bottom sheet of the lamination film is connected with its reverse side to the front side of the lower sheet substrate, and the middle sheet substrate is the basis for placing LEDs, a contactless chip module and a loop antenna on it, which has an additional electrical connection with LEDs, in turn, a loop antenna with a contactless chip module and LEDs are placed in the plane of the middle sheet substrate on its front side.

The LEDs and the contactless chip module are placed inside the area formed by the loop antenna circuit, wherein the loop antenna is formed by coils of conductive wire, and the chip module and LEDs with the loop antenna are connected in parallel.

In each of the embodiments of the invention, the middle sheet substrate, the upper sheet substrate and the lower sheet substrate are made of plastic.

Brief description of drawings

Fig. 1. Payment smart card with a contactless interface and LEDs according to the first option.

Fig. 2. Payment smart card with a contactless interface and LEDs according to the second option.

Fig. 3. Payment smart card with a contactless interface and LEDs according to the third option.

Carrying out the invention

Each of the specified technical results is achieved through the use in the design of each embodiment of a payment smart card with a contactless interface of a multilayer structure, in which there is only one base (which is the middle sheet substrate) for placing LEDs on it, a loop antenna (and an additional loop antenna in implementation options with two inductive circuits) and a chip module. In this case, the middle sheet substrate is connected on both sides to the corresponding lower and upper substrates, which cover the plane of the front and back sides of the said base. In addition, a matching sheet of lamination film is attached to the faces of the top and bottom backing. The front side of the middle backing (3) is the side to which the upper sheet backing (6) is attached (its back side) and, accordingly, the back side of the middle backing (3) is the side to which the bottom sheet backing (7) is attached (its back side).

The base and substrates are made of plastics, and the lamination films are made of polyvinyl chloride (PVC), including biodegradable and recycled PVC, as well as polycarbonate (PC), polyethylene terephthalate (PET, PETG).

The embodiments of the invention are illustrated using Fig. 1, Fig. 2, Fig. 3.

According to the first option (see Fig. 1), a payment smart card with a contactless interface and LEDs contains a loop antenna (1) electrically connected to a contactless chip module (2), a middle sheet substrate (3), an upper sheet substrate (6 ), bottom backing sheet (7), top (8) and bottom (9) sheets of lamination film. Backing sheets and lamination film sheets have a front and back side. The middle sheet backing (3) is placed between the top (6) and bottom (7) sheet backing, the top sheet (8) of the lamination film is connected with its back side to the front side of the top sheet backing (6), and the bottom sheet (9) of the lamination film is connected to its back side. the reverse side is connected to the front side of the lower sheet substrate (7), and the middle sheet substrate (3) is the basis for placing on it semiconductor LEDs (5), a contactless chip module (2), a loop antenna (1) and an additional loop antenna ( 4), electrically connected to the LEDs (5), in turn, the loop antenna (1) with a contactless chip module (2) is placed in the plane of the middle (3) sheet substrate on its reverse side, and on the front side of the middle (3) sheet LEDs and an additional antenna (4) are placed on the substrate. The placement of the loop antenna (1) and the contactless chip module (2) is carried out by implanting a sheet substrate, which is a sheet of plastic, into the plane of the middle (3). An additional loop antenna (4) and semiconductor LEDs (5) connected to it are implanted in the plane of the middle (3) sheet substrate on its front side.

The LEDs are placed inside the area formed by the contour of the additional loop antenna (4), and the contactless chip module is placed inside the area formed by the contour of the loop antenna.

The upper sheet substrate (6) and the lower sheet substrate (7) are plastic sheets. The top (8) and bottom (9) sheets of lamination film on the reverse sides have an adhesive layer for connection to the front sides of the top (6) and bottom (7) sheet backings. In this case, the reverse side of the lower sheet substrate (7) is connected to the reverse side of the middle (3) sheet substrate, and the reverse side of the upper sheet substrate (6) is connected to the front side of the middle (3) sheet substrate.

In each of the embodiments of the invention, the loop antenna and/or additional loop antenna are wire loop antennas and represent a multi-turn circuit made of copper wire, which is insulated with polyester varnish to prevent shorting of the turns among themselves, which, in turn, ensures the operability of the resonant circuit and transmitting a signal with high quality at high speed. Copper wire has good conductivity, which allows transmission to the required distance and with minimal losses. Copper is also strong and durable, making it an ideal material for antennas. An enameled, heat-resistant, high-strength wire with polyvinyl acetate insulation (PTEV-2) can be used as a wire for the antenna. The thickness of the wire is selected based on the requirements for the antenna characteristics.

The additional loop antenna is electrically connected to the semiconductor LEDs, and the loop antenna is electrically connected to the chip module in the non-contact package (contactless chip module).

The loop antenna (1) is connected to the chip module in a contactless package (2) through a direct connection by soldering.

An additional loop antenna (4) is connected to the semiconductor LEDs (5) through a direct solder connection.

The top sheet substrate (6) and the top sheet of lamination film (8) have a degree of translucency sufficient to provide a visual indication of emission from the semiconductor LEDs (5).

The introduction of a chip module in a contactless package, directly into the internal structure of the card, allows the production of the declared smart cards on existing specialized equipment, including the production of plastic sheets with a loop antenna and semiconductor LEDs on specialized equipment. Also, replacing the dual chip module with a chip module in a contactless package allows you to free up the area in the area where the chip module is placed and eliminate the need to work out additional design features in the layered structure of the card, providing for the electrical connection of the dual chip module with the antenna circuit and the ability to keep it open contact part for the payment terminal. Accordingly, the exclusion of the contact chip module from the design of the smart card and the design features of the claimed technical solution according to the first option make it possible to simplify the design of a payment smart card with a contactless interface and LEDs while maintaining its functionality, simplifying the smart card assembly technology (due to the absence of the need for ensuring contact connection between the chip module and the payment terminal). It also provides an increase in usable area for placing design elements, since space is freed up by eliminating the dual chip module from the smart card design. In addition, an additional technical result is provided, which consists in eliminating factors that affect the overlap of the LED indication during operation of the smart card. This technical result is achieved through the use of a contactless payment method, which eliminates partial or even complete overlap of the card area in which the LEDs are located by elements of the reading device or payment terminal. At the same time, the arsenal of technical means aimed at creating a payment smart card with a contactless interface and LEDs is being expanded.

In fig. 1 schematically shows all layers of a payment smart card with a contactless interface and LEDs. The physical characteristics of the card correspond to the ID-1 format in accordance with GOST R ISO/IEC 7810-2015.

Connecting semiconductor LEDs (5) of different colors with an additional loop antenna (4) makes it possible to achieve optical radiation of different colors, which significantly expands the possibilities for implementing a variety of design solutions regarding the visual design of payment smart cards. As a result of the tests, it was possible to determine the rational number of semiconductor LEDs used. The minimum number of LEDs is one, and the maximum number of LEDs is five. The maximum number is determined by test results in which the power generated by the additional loop antenna (4) with connected LEDs (5) is sufficient to provide optical radiation from five LEDs. Adding more LEDs requires adding additional elements, such as capacitors, which complicate the production of sheets of plastic with a loop antenna and LEDs, increasing the likelihood of failure due to the greater number of elements in the structure.

The upper sheet substrate (6), which is a sheet of plastic, ensures the formation of a layered structure of the smart card, protects the electrical elements of the smart card from external influences and is additionally used for printing graphic information (design) and text information for the front side of the payment smart card.

The lower sheet substrate (7), which is a sheet of plastic, ensures the formation of a layered structure of the smart card, protects the electrical elements of the smart card from external influences and is additionally used for printing graphic information (design) and text information for the reverse side of the payment smart card.

The top lamination sheet (8) is a sheet lamination film with an adhesive layer on the back side and is used to protect the front side of the smart card from external influences.

The bottom lamination sheet (9) is a sheet lamination film with an adhesive layer on its back side and is used to protect the back side of the smart card from external influences.

In fig. Figure 2 schematically shows all layers of a payment smart card with a contactless interface and LEDs. The physical characteristics of the card also correspond to the ID-1 format in accordance with GOST R ISO/IEC 7810-2015.

According to the second option (see Fig. 2), a payment smart card with a contactless interface and LEDs contains a loop antenna (1) electrically connected to a contactless chip module (2), a middle sheet substrate (3), an upper sheet substrate (6 ), bottom backing sheet (7), top (8) and bottom (9) sheets of lamination film. Backing sheets and lamination film sheets have a front and back side. The middle sheet backing (3) is placed between the top (6) and bottom (7) sheet backing, the top sheet (8) of the lamination film is connected with its back side to the front side of the top sheet backing (6), and the bottom sheet (9) of the lamination film is connected to its back side. the reverse side is connected to the front side of the lower sheet substrate (7), and the middle sheet substrate (3) is the basis for placing on it semiconductor LEDs (5), a contactless chip module (2), a loop antenna (1) and an additional loop antenna ( 4), electrically connected to the LEDs (5). In turn, a loop antenna (1) with a contactless chip module (2) and an additional loop antenna (4) with LEDs are placed in the plane of the middle sheet substrate (3) on its front side. The placement of the loop antenna (1) and the contactless chip module (2) is carried out by implanting into the plane of the middle (3) sheet substrate from its front side, which is a sheet of plastic. An additional loop antenna (4) and semiconductor LEDs (5) connected to it are implanted in the plane of the middle (3) sheet substrate, also on its front side.

The LEDs are placed inside the area formed by the circuit of the additional loop antenna (4), and the contactless chip module is placed inside the area formed by the circuit of the loop antenna (1). The circuit of the additional loop antenna (4) is located inside the area formed by the circuit of the loop antenna (1) and free from the placement of the contactless chip module (2). This arrangement allows for efficient use of space on the middle sheet substrate and eliminates the possibility of electrical elements of the smart card intersecting or overlapping each other.

The upper sheet substrate (6) and the lower sheet substrate (7) are plastic sheets. The top (8) and bottom (9) sheets of lamination film on the reverse sides have an adhesive layer for connection to the front sides of the top (6) and bottom (7) sheet backings. In this case, the reverse side of the lower sheet substrate (7) is connected to the reverse side of the middle (3) sheet substrate, and the reverse side of the upper sheet substrate (6) is connected to the front side of the middle (3) sheet substrate.

The additional loop antenna is electrically connected to the semiconductor LEDs, and the loop antenna is electrically connected to the chip module in the non-contact package (contactless chip module).

The loop antenna (1) is connected to the chip module in a contactless package (2) through a direct connection by soldering.

An additional loop antenna (4) is connected to the semiconductor LEDs (5) through a direct solder connection.

The top sheet substrate (6) and the top sheet of lamination film (8) have a degree of translucency sufficient to provide a visual indication of emission from the semiconductor LEDs (5).

As can be seen from the presented design, the payment smart card according to the second option differs from the smart card according to the first option only in the arrangement of elements that are placed on the middle (3) sheet substrate.

Accordingly, as previously indicated, the introduction of a chip module in a contactless package, directly into the internal structure of the card, allows the production of the declared smart cards on existing specialized equipment, including the production of plastic sheets with a loop antenna and semiconductor LEDs on specialized equipment. The exclusion of the contact chip module from the design of the smart card and the design features of the claimed technical solution according to the second option make it possible to simplify the design of a payment smart card with a contactless interface and LEDs while maintaining its functionality, simplifying the smart card assembly technology (due to the absence of the need to provide a contact connecting the chip module to the payment terminal). It also provides an increase in usable area for placing design elements, since space is freed up by eliminating the dual chip module from the smart card design. In addition, an additional technical result is provided, which consists in eliminating factors that affect the overlap of the LED indication during operation of the smart card. This technical result is achieved through the use of a contactless payment method, which eliminates partial or even complete overlap of the card area in which the LEDs are located by elements of the reading device or payment terminal. At the same time, the arsenal of technical means aimed at creating a payment smart card with a contactless interface and LEDs is being expanded.

In the device according to the second option, the connection of semiconductor LEDs (5) of different colors with an additional loop antenna (4) makes it possible to achieve optical radiation of different colors, which significantly expands the possibilities for implementing a variety of design solutions regarding the visual design of payment smart cards. As a result of the tests, it was possible to determine the rational number of semiconductor LEDs used. The minimum quantity is one LED, and the maximum quantity is four LEDs, due to the smaller area (and correspondingly lower antenna power) to accommodate the additional antenna loop (due to the placement of the loop antenna and the additional loop antenna on one side of the middle substrate sheet (3)). The maximum quantity is determined by the test results in which the power generated by the loop antenna (4) with the connected LEDs (5) is sufficient to provide optical radiation from four LEDs. Adding more LEDs requires adding additional elements, such as capacitors, which complicate the production of sheets of plastic with a loop antenna and LEDs, increasing the likelihood of failure due to the greater number of elements in the structure.

As in the first embodiment, the upper sheet substrate (6), which is a sheet of plastic, ensures the formation of a layered structure of the smart card, protects the electrical elements of the smart card from external influences and is additionally used for printing graphic information (design) and text information for the front sides of the payment smart card.

The lower sheet substrate (7), which is a sheet of plastic, ensures the formation of a layered structure of the smart card, protects the electrical elements of the smart card from external influences and is additionally used for printing graphic information (design) and text information for the reverse side of the payment smart card.

The top lamination sheet (8) is a sheet lamination film with an adhesive layer on the back side and is used to protect the front side of the smart card from external influences.

The bottom lamination sheet (9) is a sheet lamination film with an adhesive layer on its back side and is used to protect the back side of the smart card from external influences.

The top sheet substrate (6) and the top sheet of lamination film (8) have a degree of translucency sufficient to provide a visual indication of emission from the semiconductor LEDs (5).

In fig. 3 schematically shows all layers of a payment smart card with a contactless interface and LEDs. The physical characteristics of the card also correspond to the ID-1 format in accordance with GOST R ISO/IEC 7810-2015.

According to the third option (see Fig. 3), a payment smart card with a contactless interface and LEDs contains a loop antenna (1) electrically connected to a contactless chip module (2), a middle sheet substrate (3), an upper sheet substrate (6 ), bottom backing sheet (7), top (8) and bottom (9) sheets of lamination film. Backing sheets and lamination film sheets have a front and back side. The middle sheet backing (3) is placed between the top (6) and bottom (7) sheet backing, the top sheet (8) of the lamination film is connected with its back side to the front side of the top sheet backing (6), and the bottom sheet (9) of the lamination film is connected to its back side. the reverse side is connected to the front side of the lower sheet substrate (7). Moreover, the middle sheet substrate (3) is the basis for placing LEDs (5), a contactless chip module (2) and a loop antenna (1), which has an additional electrical connection with the LEDs (5). In turn, the loop antenna (1) with the contactless chip module (2) and LEDs (5) are placed in the plane of the middle (3) sheet substrate on its front side.

The LEDs (5) and the contactless chip module (2) are placed inside the area formed by the contour of the loop antenna (1), wherein the loop antenna (1) is formed by turns of conductive wire, and the chip module (2) and LEDs (5) with the loop antenna have a parallel connection.

The upper sheet substrate (6) and the lower sheet substrate (7) are plastic sheets. The top (8) and bottom (9) sheets of lamination film on the reverse sides have an adhesive layer for connection to the front sides of the top (6) and bottom (7) sheet backings. In this case, the reverse side of the lower sheet substrate (7) is connected to the reverse side of the middle (3) sheet substrate, and the reverse side of the upper sheet substrate (6) is connected to the front side of the middle (3) sheet substrate.

The loop antenna (1) is connected to the chip module in a contactless package (2) and semiconductor LEDs (5) through a direct connection by soldering.

The top sheet substrate (6) and the top sheet of lamination film (8) have a degree of translucency sufficient to provide a visual indication of emission from the semiconductor LEDs (5).

As can be seen from the presented design, the payment smart card according to the third option differs from the smart card according to the first and second options only in the arrangement of elements that are placed on the middle (3) sheet substrate, and in the absence of an additional loop antenna.

Accordingly, as previously indicated, the introduction of a chip module in a contactless package, directly into the internal structure of the card, allows the production of the declared smart cards on existing specialized equipment, including the production of plastic sheets with a loop antenna and semiconductor LEDs on specialized equipment. The exclusion of the contact chip module from the design of the smart card and the design features of the claimed technical solution according to the third option make it possible to simplify the design of a payment smart card with a contactless interface and LEDs while maintaining its functionality, simplifying the smart card assembly technology (due to the absence of the need to provide a contact connecting the chip module to the payment terminal). It also provides an increase in usable area for placing design elements, since space is freed up by eliminating the dual chip module from the smart card design. In addition, an additional technical result is provided, which consists in eliminating factors that affect the overlap of the LED indication during operation of the smart card. This technical result is achieved through the use of a contactless payment method, which eliminates partial or even complete overlap of the card area in which the LEDs are located by elements of the reading device or payment terminal. At the same time, the arsenal of technical means aimed at creating a payment smart card with a contactless interface and LEDs is being expanded.

Connecting semiconductor LEDs (5) of different colors with a loop antenna (1) makes it possible to achieve optical radiation of different colors, which significantly expands the possibilities for implementing a variety of design solutions regarding the visual design of payment smart cards. As a result of the tests, it was possible to determine the rational number of semiconductor LEDs used. The minimum quantity is one LED, and the maximum quantity is two LEDs. The maximum quantity is determined by the test results, in which the power generated by the loop antenna (1) with a chip module in a contactless package (2) and semiconductor LEDs (5) is sufficient to provide optical radiation from two LEDs. Adding more LEDs requires adding additional elements, such as capacitors, which complicate the production of sheets of plastic with a loop antenna and LEDs, increase the likelihood of failures due to the greater number of elements in the structure, and increase the cost of the final product - a payment smart card.

As in previous embodiments, the top sheet substrate (6), which is a sheet of plastic, ensures the formation of a layered structure of the smart card, protects the electrical elements of the smart card from external influences and is additionally used for printing graphic information (design) and text information for the front sides of the payment smart card.

The lower sheet substrate (7), which is a sheet of plastic, ensures the formation of a layered structure of the smart card, protects the electrical elements of the smart card from external influences and is additionally used for printing graphic information (design) and text information for the reverse side of the payment smart card.

The top lamination sheet (8) is a sheet lamination film with an adhesive layer on the back side and is used to protect the front side of the smart card from external influences.

The bottom lamination sheet (9) is a sheet lamination film with an adhesive layer on its back side and is used to protect the back side of the smart card from external influences.

The top sheet substrate (6) and the top sheet of lamination film (8) have a degree of translucency sufficient to provide a visual indication of emission from the semiconductor LEDs (5).

It should be noted that, regardless of the design used, a design is printed on the front, back, or both sides of the payment smart card, which is selected for the proposed arrangement of LEDs, or sheets of plastic with a loop antenna and LEDs are produced for the required design. The location of semiconductor LEDs on a sheet of plastic can vary; the minimum distance of LEDs from the antennas and the minimum distance between the displayed areas of the LEDs is 10 mm, which is determined by the size of their housings and tolerances for displacement of specialized technological equipment. In this case, issuing banks have additional opportunities to implement a large number of creative ideas, for example, to additionally highlight their logo or highlight a banking product in collaboration with any brand manufacturer of IT products, computer or virtual games, etc. Replacing a dual chip module with a chip module in a non-contact package allows you to free up design space in the area where the chip module is placed. Also, taking into account the fact that the integration of LEDs does not affect the standard production process of payment smart cards, additional elements of card finishing, such as varnishing, remain available, including in the area of the previously located contact pad of the dual chip module.

Regardless of the design used, in accordance with Fig. 1, Fig. 2 and Fig. 3, a payment smart card with a contactless interface and LEDs is produced as follows.

All layers of a payment smart card are connected through press lamination, which allows for strong adhesion of the layers and the formation of a single blank. Next, the laminated card blanks are cut out on specialized equipment to ID-1 format.

There is no need to integrate a dual chip module into the cut-out blanks, because The chip module in contactless packaging is already inside the laminated die-cut payment card and is capable of ensuring the operable state of the resonant circuit, because has similar technical characteristics as the dual chip module, with the exception of the physical parameters of its housing.

A payment smart card with a contactless interface and LEDs works as follows. On personalized industrial equipment, the user’s personal payment data and the payment application of the issuing bank are recorded on the chip module (2), which interacts through the payment system with the merchant’s acquiring bank when conducting a payment transaction. The data is stored in a form encrypted with crypto keys and is protected from overwriting or modification. When the payment smart card is within the range of the contactless reader, the resonant circuit formed by the loop antenna (1) and the chip module (2) ensures the transmission of encoded information via a radio frequency channel. At the same time, when the payment smart card is in the range of the contactless reader, the resonant circuit formed by the loop antenna (4) or loop antenna (1) (in the case of using only one loop antenna) ensures the passage of electric current through the semiconductor LEDs ( 5) and, accordingly, creates optical radiation visible to the eye.

The choice of a particular design option for a payment smart card with a contactless interface and LEDs is determined by the required final result in terms of card thickness, the presence or absence of embossing (extrusion of personalized symbols on the card), the required number of LEDs and the technical characteristics of the chip module in a contactless package.

Below are possible options for the implementation and acquisition.

1. Design according to the first option (see Fig. 1).

1.1. Payment smart card with a contactless interface and one green semiconductor LED.

When connected by press lamination of a loop antenna (1) and a chip module in a non-contact package (2), implanted in a plane in a sheet of plastic (3), 0.500 mm thick, an additional loop antenna (4) connected to semiconductor LEDs (5) , implanted in a plane into a sheet of plastic (3) from the front side, sheets of plastic (6) and (7), each 0.100 mm thick, as well as sheets of lamination film (8) and (9) with an adhesive layer, the thickness of which is 0.050 mm each . Taking into account shrinkage during press lamination, the final thickness of the payment smart card will be about 0.780 mm (taking into account shrinkage during press lamination of 0.02 mm).

1.2. Payment smart card with a contactless interface and two semiconductor LEDs in white and blue.

When connected by press lamination of a loop antenna (1) and a chip module in a non-contact package (2), implanted in a plane in a sheet of plastic (3), 0.500 mm thick, an additional loop antenna (4) connected to semiconductor LEDs (5) , implanted in a plane into a sheet of plastic (3) from the front side, sheets of plastic (6) and (7), each 0.100 mm thick, as well as sheets of lamination film with an adhesive layer (8) and (9), the thickness of which is 0.050 mm each . Taking into account shrinkage during press lamination, the final thickness of the payment smart card will be about 0.780 mm (taking into account shrinkage during press lamination of 0.02 mm).

These options are recommended in the presence of embossing, because Two unconnected loop antennas located on different sides of the sheet allow you to use ¾ size antennas, which will not interrupt them when embossing personalized symbols.

2. Design according to the second option (see Fig. 2).

2.1 Payment smart card with a contactless interface and one red semiconductor LED.

When connected by press lamination of a loop antenna (1) and a chip module in a non-contact package (2), implanted in a plane in a sheet of plastic (3), 0.450 mm thick, an additional loop antenna (4) connected to semiconductor LEDs (5) , implanted in a plane into a sheet of plastic (3), sheets of plastic (6) and (7), each 0.150 mm thick, as well as sheets of lamination film with an adhesive layer (8) and (9) each 0.050 mm thick. Taking into account shrinkage during press lamination, the final thickness of the payment smart card will be about 0.830 mm (taking into account shrinkage during press lamination of 0.02 mm).

2.2 Payment smart card with a contactless interface and two semiconductor LEDs of yellow and red colors.

When connected by press lamination of a loop antenna (1) and a chip module in a non-contact package (2), implanted in a plane in a sheet of plastic (3), 0.500 mm thick, an additional loop antenna (4) connected to semiconductor LEDs (5) , implanted in a plane into a sheet of plastic (3), sheets of plastic (6) and (7), each 0.100 mm thick, as well as sheets of lamination film with an adhesive layer (8) and (9) each 0.050 mm thick. Taking into account shrinkage during press lamination, the final thickness of the payment smart card will be about 0.780 mm (taking into account shrinkage during press lamination of 0.02 mm).

This design is not recommended in the presence of embossing, because when extruding personalized symbols, the cams of the personalization equipment will interrupt the antenna, which will result in the inoperability of the resonant circuit and, accordingly, the impossibility of paying with such payment smart cards.

3. Design according to the third option (see Fig. 3).

3.1 Payment smart card with a contactless interface and one or two semiconductor LEDs.

When connected by press lamination of a loop antenna (1), a chip module in a contactless package (2) and semiconductor LEDs (5), implanted in a plane into a plastic sheet (3), 0.500 mm thick, plastic sheets (6) and (7 ), each 0.100 mm thick, as well as sheets of lamination film with an adhesive layer (8) and (9) each 0.060 mm thick. Taking into account shrinkage during press lamination, the final thickness of the payment smart card will be about 0.800 mm (taking into account shrinkage during press lamination of 0.02 mm).

This design is not recommended in the presence of embossing, because when extruding personalized symbols, the cams of the personalization equipment will interrupt the antenna, which will result in the inoperability of the resonant circuit and, accordingly, the impossibility of paying with such payment smart cards.

Claims (10)

1. Payment smart card with a contactless interface and LEDs, containing a loop antenna (1) electrically connected to a contactless chip module (2), a middle sheet substrate (3), an upper sheet substrate (6), a lower sheet substrate (7) , top (8) and bottom (9) sheets of lamination film, wherein the backing sheets and lamination film sheets have a front and back side, characterized in that the backing sheets and lamination film sheets are combined into a multilayer structure formed by joining the backing sheets and sheets lamination film so that the middle sheet backing (3) is placed between the top (6) and bottom (7) sheet backing, the top sheet (8) of the lamination film is connected with its back side to the front side of the top sheet backing (6), and the bottom sheet ( 9) of the lamination film, its reverse side is connected to the front side of the lower sheet substrate (7), and the middle sheet substrate (3) is the basis for placing LEDs (5), a contactless chip module (2), a loop antenna (1) and additional loop antenna (4), electrically connected to the LEDs (5), in turn, the loop antenna (1) with a contactless chip module (2) is placed in the plane of the middle (3) sheet substrate on its reverse side, and on the front side of the middle (3) LEDs and an additional antenna (4) are placed on the sheet substrate. 2. Payment smart card according to claim 1, characterized in that the LEDs are located inside the area formed by the circuit of the additional loop antenna (4), and the contactless chip module is placed inside the area formed by the circuit of the loop antenna (1), and the minimum distance of the LEDs from antennas is 10 mm. 3. Payment smart card according to claim 1, characterized in that the loop antenna (1) and the additional loop antenna (4) are formed by turns of conductive wire, and the number of LEDs is from 1 to 5. 4. Payment smart card according to claim 1, characterized in that the middle sheet substrate (3), the upper sheet substrate (6) and the lower sheet substrate (7) are made of plastic. 5. Payment smart card with a contactless interface and LEDs, containing a loop antenna (1) electrically connected to a contactless chip module (2), a middle sheet substrate (3), an upper sheet substrate (6), a lower sheet substrate (7) , top (8) and bottom (9) sheets of lamination film, wherein the backing sheets and lamination film sheets have a front and back side, characterized in that the backing sheets and lamination film sheets are combined into a multilayer structure formed by joining the backing sheets and sheets lamination film so that the middle sheet backing (3) is placed between the top (6) and bottom (7) sheet backing, the top sheet (8) of the lamination film is connected with its back side to the front side of the top sheet backing (6), and the bottom sheet ( 9) of the lamination film, its reverse side is connected to the front side of the lower sheet substrate (7), and the middle sheet substrate (3) is the basis for placing LEDs (5), a contactless chip module (2), a loop antenna (1) and additional loop antenna (4), electrically connected to the LEDs (5), in turn, the loop antenna (1) with a contactless chip module (2) and the additional loop antenna (4) with LEDs are placed in the plane of the middle (3) sheet substrate on its front side. 6. Payment smart card according to claim 5, characterized in that the LEDs are placed inside the area formed by the contour of the additional loop antenna (4), and the contactless chip module is placed inside the area formed by the contour of the loop antenna (1), and the contour of the additional loop antenna antenna (4) is located inside the area formed by the contour of the loop antenna (1) and free from the placement of the contactless chip module (2). 7. Payment smart card according to claim 5, characterized in that the loop antenna (1) and the additional loop antenna (4) are formed by turns of conductive wire, and the number of LEDs is from 1 to 4, while the middle sheet substrate (3), the upper sheet substrate (6) and the lower sheet substrate (7) are made of plastic. 8. Payment smart card with a contactless interface and LEDs, containing a loop antenna (1) electrically connected to a contactless chip module (2), a middle sheet substrate (3), an upper sheet substrate (6), a lower sheet substrate (7) , top (8) and bottom (9) sheets of lamination film, wherein the backing sheets and lamination film sheets have a front and back side, characterized in that the backing sheets and lamination film sheets are combined into a multilayer structure formed by joining the backing sheets and sheets lamination film so that the middle sheet backing (3) is placed between the top (6) and bottom (7) sheet backing, the top sheet (8) of the lamination film is connected with its back side to the front side of the top sheet backing (6), and the bottom sheet ( 9) the back side of the lamination film is connected to the front side of the lower sheet substrate (7), and the middle sheet substrate (3) is the basis for placing on it LEDs (5), a contactless chip module (2) and a loop antenna (1), which has an additional electrical connection with the LEDs (5), in turn, the loop antenna (1) with the contactless chip module (2) and LEDs (5) are placed in the plane of the middle (3) sheet substrate on its front side. 9. Payment smart card according to claim 8, characterized in that the LEDs (5) and the contactless chip module (2) are placed inside the area formed by the contour of the loop antenna (1), and the loop antenna (1) is formed by turns of conductive wire, and the chip module (2) and LEDs (5) with a loop antenna have a parallel connection. 10. Payment smart card according to claim 8, characterized in that the number of LEDs is from 1 to 2, while the middle sheet substrate (3), the upper sheet substrate (6) and the lower sheet substrate (7) are made of plastic.