RU189039U1 - NON-CONTACT PAYMENT MODULE FOR PORTABLE DEVICE - Google Patents

Abstract

The invention relates to the field of contactless payment devices, in particular to contactless payment modules that are integrated into wearable devices. The contactless payment module includes a coil antenna formed by coils of conductive material, a microchip whose leads are connected to the coaxial antenna terminals, and a capacitive load connected in parallel to the coil antenna located on a dielectric substrate. The turns of the loop antenna are located on a flat dielectric substrate with the formation in terms of a closed figure consisting of two symmetrical parts, each of which has essentially the shape of an arc. The mentioned symmetric parts are connected with each other with the formation on one side of the mentioned closed figure of the angular depression, and on the opposite side - of the angular protrusion. The microchip is located essentially in the center of the said closed figure, and the dielectric substrate has a lateral surface essentially congruent to the said closed figure. The utility model makes it possible to increase the usability of the contactless payment module, to expand the area of its application, to reduce the time costs in its manufacture.

Description

The invention relates to the field of contactless payment devices, in particular, to contactless payment modules that are integrated into wearable devices.

Contactless payment modules are widely known, including an antenna located on a dielectric substrate, which are part of payment facilities such as smart cards (see, for example, RU 2251742 C2, 07.26.2017). The disadvantage of such modules is the need to use a specific means for making transactions (cards), which is inconvenient for the user.

A contactless payment module is also known, which includes a frame antenna formed by turns of conductive material, a microchip whose terminals are connected to the terminals of a frame antenna, and a capacitor connected in parallel to the frame antenna located on a dielectric substrate, which is part of a payment medium made in the form of a portable the device, namely, rings (see, for example, RU 183111 U1, 11.09.2018). This well-known contactless payment module is adopted as the closest analogue of the claimed contactless payment module.

The disadvantage of the closest analogue is that this contactless payment module is located on a dielectric substrate having a shape that allows you to place the payment tool on the user's finger. As a result, when making a payment, the user's hand must be clenched into a fist, which creates certain inconveniences and limitations in use. In addition, such an implementation of the contactless payment module requires additional time in the manufacture of rings of various sizes for users with different physical data and the need, as a result, for the certification of each new product. Another disadvantage of the known contactless payment module can be attributed to the limitations of its use, due to the possibility of integrating only into a particular wearable device (ring) and the impossibility, as a result, of integrating into other wearable devices, including accessories.

The technical problem solved by the claimed utility model is to create a contactless payment module for a wearable device, made in the form of a compact unit, structurally independent of the wearable device, which can be integrated into wearable devices of various shapes, sizes, etc.

When this is achieved, the technical result consists in increasing the usability of the module of contactless payment, expanding the scope of its application, reducing time spent on its manufacture, expanding the arsenal of technical means of contactless payment for a wearable device.

The technical problem is solved, and the specified technical result is achieved in a contactless payment module that includes a frame antenna formed by turns of conductive material, a microchip, the terminals of which are connected to the terminals of a frame antenna, and a capacitor connected in parallel to the frame antenna located on a dielectric substrate. The coils of the loop antenna are located on the above-mentioned dielectric substrate with the formation in terms of a closed figure consisting of two symmetrical parts, each of which has essentially the shape of an arc. Said symmetrical parts are mated with each other to form, on one side of the said closed figure, an angular depression, preferably with an angle of less than 90 degrees, preferably having a smooth rounding, and from the opposite side, an angular protrusion, preferably with an angle of more than 90 degrees. The microchip is located essentially in the center of the said figure, inside the turns of the loop antenna. The dielectric substrate has a side surface that is substantially congruent to the figure. The distance between the outermost turn of the frame antenna and the side surface of the dielectric substrate is preferably from 0.3 to 1 mm.

The described configuration of the claimed contactless payment module and the topology of the placement of its components allow, with a sufficiently compact size of the module, to ensure its rigidity, which makes the contactless payment module applicable in a wide variety of wearable devices. Thus, the contactless payment module can be used in a wearable device selected from the group that includes a ring, bracelet, pendant, key chain, and other accessory.

The technical problem is solved, and the specified technical result is also achieved in particular versions of the contactless payment module, according to one of which the distance between two points most distant from each other in the plane of symmetry of the said closed figure is preferably from 75 to 80% of the distance between two points of maximum curvature of each of the arcs.

In another particular embodiment of the contactless payment module, the thickness of the dielectric substrate is from 0.76 to 0.85 mm.

In another private embodiment of the contactless payment module, the antenna coils are formed from wire. The thickness of the turns of the antenna is preferably from 0.05 to 0.15 mm.

Further, the utility model is described in more detail with reference to the figures.

FIG. 1 shows a schematic depiction of the claimed contactless payment module in the plan.

FIG. 2 shows a schematic depiction of the claimed contactless payment module in the preferred embodiment, in isometric view.

The contactless payment module shown in FIG. 1 and FIG. 2 includes a frame antenna 1 formed by coils (for example, wire) of a conductive material (for example, copper), a microchip 2, the terminals of which are connected to the terminals of the frame antenna 1, and a capacitive load (capacitor) 3 connected in parallel to the frame antenna 2, located on a flat dielectric (eg plastic) substrate 4.

The turns of the loop antenna 1 are located on a flat dielectric substrate 4 with the formation in terms of a closed figure consisting of two symmetrical parts 1a and 1b, each of which has essentially the shape of an arc. Said symmetrical parts 1a and 1b are associated with each other to form, on one side, said closed figure an angular depression, preferably having a smooth rounding, preferably with an angle less than 90 degrees, and from the opposite side — an angular protrusion, preferably with an angle greater than 90 degrees. The distance between two points as far apart as possible in the plane of symmetry of the above figure may, but not necessarily, be from 75 to 80% of the distance between two points of maximum curvature of each of the arcs.

The form of the mentioned closed figure may be a stylized image of the heart and in the Cartesian coordinate system described, for example, by the following equation:

.

.

The dielectric substrate 4 has a side surface that is substantially congruent to said closed figure. The distance between the outermost turn of the frame antenna 1 and the side surface of the dielectric substrate 4 is preferably from 0.3 to 1 mm. A larger value of this distance can lead to an unreasonable increase in the total size of the contactless payment module, and a smaller one - to possible damage to the outer turns of loop antenna 1 when integrating the contactless payment module into a wearable device.

Compared with the traditional frame antenna, which has a circular, square or rectangular shape, the frame antenna 1 of the described form with its corresponding substrate form 4 provides for a more compact implementation of the stated contactless payment module while maintaining its sufficient rigidity and ease of manufacture. This is provided as a result of the arrangement of the turns of the frame antenna 1 and the implementation of the substrate 4 in the form of a symmetric (i.e. evenly perceiving possible loads) closed figure having a smaller, but nonetheless sufficient surface area for transmitting the radio frequency signal without distortion , determined by the shape of the shape itself and, as a result, do not require additional technological methods for their formation, providing, in addition, an additional increase in the resistance of the module to mechanical im loads.

Microchip 2 is located essentially in the center of the figure, i.e. inside the turns of loop antenna 1, which also provides the contactless payment module with compactness and required rigidity and, therefore, versatility when integrated into various wearable devices.

It is preferable to perform the claimed contactless payment module having an external protective shell 5 (see FIG. 2) in which the frame antenna 1, the microchip 2 and the capacitive load 3 provided by any known from the prior art appropriately are placed, including the original placement of the specified module components in the fragment dielectric plate.

The claimed contactless payment module is used in the traditional way for such an appointment. When integrating a contactless payment module into a wearable device, for example, a ring, the wearable device is brought to the contactless payment terminal and carries out a transaction (payment). If necessary, the terminal can additionally request information to identify the owner of the wearable device, in particular, the pin code. Then the user enters the requested information, and if approved, the transaction is carried out.

The claimed contactless payment module, due to its compact and rigid configuration, can be easily integrated into any suitable wearable device, in particular, in an accessory, including, but not limited to, ring, bracelet, pendant, key ring. The arrangement of the turns of the loop antenna on a flat surface ensures convenient use of the module as part of the payment means - a wearable device. It is possible to perform a contactless payment module on a separate production line, which minimizes the time spent on manufacturing both the contactless payment module and the wearable device, providing the possibility of parallel technological operations, and also allows testing and subsequent certification of the contactless payment module separately from the final product, and in its composition.

Claims (9)

1. A contactless payment module for a wearable device that includes a loop antenna formed by turns of conductive material, a microchip whose terminals are connected to the leads of the loop antenna, and a capacitive load connected in parallel to the loop antenna, which are located on the dielectric substrate antennas are located on a flat dielectric substrate with the formation of a closed figure consisting of two symmetrical parts, each of which has the shape of an arc, said symmetric Asti conjugate with each other to form one side of said closed shape corner depressions, and the opposite side - the angular protrusion microchip is positioned within the loop antenna coils, and the dielectric substrate has a lateral surface substantially congruent to said closed figure. 2. Module according to claim 1, characterized in that the distance between the outermost turn of the coil antenna and the side surface of the dielectric substrate is from 0.3 to 1 mm. 3. Module according to claim 1, characterized in that the angular protrusion is made with an angle greater than 90 degrees. 4. Module according to claim. 1, characterized in that the angular depression is made with an angle less than 90 degrees. 5. Module according to claim. 1, characterized in that the corner depression has a smooth rounding. 6. The module according to claim 1, characterized in that the distance between two points most distant from each other in the plane of symmetry of said closed figure is from 75 to 80% of the distance between two points of maximum curvature of each of the arcs. 7. Module according to claim. 1, characterized in that the thickness of the dielectric substrate is from 0.76 to 0.85 mm. 8. Module according to claim. 1, characterized in that the turns of the coil antenna are made of wire. 9. Module according to claim. 1, characterized in that the thickness of the turns of the loop antenna is 0.05 to 0.15 mm.

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