RU168563U1 - CONTACTLESS IDENTIFICATION SMART CARD WITH THE POSSIBILITY OF USING SEPARABLE FRAGMENTS AS AN ACTIVATED INDEPENDENT RFID-IDENTIFIERS - Google Patents

Abstract

The invention relates to the design of a contactless smart card. The technical result is the expansion of the functionality of a contactless smart card, the activation of which takes place at the time necessary for the user at his request. It is also possible to use a smart card as a means of payment, where the possibility of repeated debiting of funds as a result of unintentional repeated application of a card to a reader, turnstile validator is excluded. In addition, it is possible to use a smart card as a means of covert signaling of an alarm, including the ability to identify the one who sent the signal. This technical result is achieved due to the fact that a contactless identification smart card containing an active main RFID tag having a line for dividing the card into fragments, characterized in that it contains an additional RFID tag, which has a shunt circuit, which is a conductive connection using electric a conductor connected in contact with an additional RFID tag, and portions of this shunt circuit pass through two adjacent fragments of the card and are structurally connected to the card so that in the normal unbroken state of the card, this shunt circuit is in the state of working contact, and in the state of the indicated adjacent fragments, this shunt circuit is in a state of broken contact, while the additional RFID tag in the state of the working contact of the shunt circuit of the additional RFID tag is inactive th state, and are able to

Description

The utility model relates to the design of a contactless smart card.

Contactless identification smart cards are equipped with an integrated radio frequency tag (RFID tag) - an antenna, and an electronic module - an integrated microcircuit (chip) connected to the antenna. These cards allow the exchange of information using non-contact electromagnetic coupling between the antenna of the card and the antenna located in the reader. Contactless smart cards are often used as a means of access to the transport network as a means of payment, as well as as a means of identifying personnel.

Known patent RU 2251742 (publ.: 05/10/2005) for the invention, which describes a contactless or combined contact-contactless chip card containing an antenna on a substrate, while the antenna contains at least one turn made on the substrate by screen printing method with using electrically conductive paint, two card cases on each side of the substrate, each of which consists of at least one layer of plastic, and one microchip or one module connected to the antenna, characterized in that the substrate is made of paper and contains IT cuts in each corner, at the level of which are soldered to each other, two of the card body, the card at the fold is able to delaminate at the site of impact bending forces that allows then to detect intentional damage, as the card retains the traces of the fold.

The closest analogue is a contactless smart card (patent RU 92558U, publ.: 20.03.2010), made in the form of a substrate with an antenna located on it, containing several turns and two layers of a card on each side of the substrate, and one microchip or one module, connected to the antenna, characterized in that the antenna further includes a conductive connection, the closing part of the turns of the antenna, while the conductive connection is located on a detachable portion of the smart card.

Known solutions are aimed at protecting a contactless smart card from illegal use. They are limited in their functionality exclusively by the microchip function of the card.

The objective of the utility model is to expand the functionality of the card.

The technical result is the expansion of the functionality of a contactless smart card, in which the activation of additional RFID tags occurs at a time necessary for the user at his request. It is also possible to use a smart card as a means of payment, which excludes the possibility of repeated debiting of funds in the event of unintentional repeated attachment of a card to a reader, turnstile validator. In addition, it is possible to use a smart card as a means of covertly signaling an alarm, while, as an option, it is possible to identify the signal that has been sent.

The specified technical result is achieved due to the fact that a contactless identification smart card is declared containing an active main RFID tag having a line for dividing the card into fragments, characterized in that it contains an additional RFID tag that has a shunt circuit, which is a conductive connection with using an electrical conductor connected in contact with an additional RFID tag, and sections of this shunt circuit pass through two adjacent fragments of the card and are structurally connected to the cards so that in the normal unbroken state of the card, this shunt circuit is in a state of working contact, and in the state of separated indicated adjacent fragments, this shunt circuit is in a state of broken contact, with the additional RFID tag in the state of the working contact of the shunt circuit of an additional RFID tag made in an inactive state, and in the condition of a broken contact of this shunt circuit has an active state as an additional RFID tag.

Preferably, in one part of the card, separated by a line for dividing the card into fragments, contains the active main RFID tag, and in another part of the card an additional RFID tag.

Preferably, the active primary RFID tag and the secondary RFID tag are located in different fragments of the map.

Preferably, the smart card has at least one fragment that does not contain RFID tags, and a portion of the shunt circuit of the secondary RFID tag or a portion of the shunt circuit of the main RFID tag or portions of both shunt circuits passes through this fragment of the card.

Preferably, the active primary RFID tag and the secondary RFID tag are located within one of the map fragments.

It is also conceivable that a contactless smart card contains at least two additional RFID tags, each having at least one shunt circuit, which is an electrical conductor or a conductive connection containing at least one electrical conductor connected in contact with the antenna of the corresponding additional RFID -tag, or connected in contact with the terminals of the integrated circuit of the corresponding additional RFID-tag, and parts of this shunt circuit pass through two adjacent fragments card and are structurally connected to the card so that in the normal unbroken state of the card, this shunt circuit is in a state of working contact, and in the state of separated indicated adjacent fragments, this shunt circuit is in a state of broken contact, while in the broken state of the antenna contact, each of the additional RFID tags in the state of the working contact of the shunt circuit of this additional RFID tag are made in the inactive state, and in the state of the broken contact of this shunt circuit an active state as an optional RFID-tags.

It is preferable that in one fragment of the card, it contains the active main RFID tag and does not contain additional RFID tags.

Preferably, the smart card has at least one fragment that does not contain RFID tags, through which a section of one or sections of several shunt circuits from among the shunt circuits of the main and additional RFID tags pass.

Preferably, the active primary RFID tag and one of the additional RFID tags are located within one of the map fragments.

A smart card may also be configured such that:

- the antenna of the active main RFID tag passes through two adjacent fragments of the card so that in the normal unbroken state of the card, the antenna is in the state of working contact, and in the state of the separated indicated adjacent fragments, the antenna is in the state of broken contact, while the characteristics of the antenna are changed so that the main RFID tag, falling within the range of the working RFID reader, does not generate a response radio signal necessary for the reader to receive power and the main RFID tag loses its working spine;

- the main RFID tag has at least one shunt circuit, which is an electrical conductor or conductive connection containing at least one electrical conductor connected in contact with the deactivating terminals of the integrated circuit of the main RFID tag, and parts of this shunt circuit pass through two adjacent fragments cards and are structurally connected to the card so that in the normal non-destroyed state of the card, this shunt circuit is in the state of working contact, and in the state of separated of adjacent adjacent fragments, this shunt circuit is in a broken contact state, while the main RFID tag in the working contact state of the shunt circuit of the main RFID tag is in the active state, and in the broken contact state of this shunt circuit has an inactive state;

- the lines for dividing the map into fragments are made in the form of lines of breaking or breaking, or tearing, or cutting, or notching, or perforation, or changes in the thickness of the map, or the boundaries of materials, or the boundaries of structural elements, or internal cavities, or boundary lines of contact of layers, while the design of the card provides the ability to separate fragments along the agreed line with acceptable accuracy;

- at least one fragment of the card is made with one or more structural elements protruding in the direction of the adjacent fragment, covering at least one electrical conductor from among the electrical conductors of the shunt circuits of the main and additional RFID tags, or inextricably connected to this conductor and intended for rupture of this conductor during the separation of fragments, while the sections of this electrical conductor pass through two adjacent fragments of the card along the line of separation of the card n but fragments;

- card fragments are made in the form of card layers connected to each other, with the possibility of separating fragments in layers, while sections of one or more conductors from among the electrical conductors of the shunt circuits of the main and additional RFID tags are made in two or more card layers.

Brief Description of the Drawings

In FIG. 1 schematically depicts a possible example of such a design of a contactless smart card that contains an additional RFID tag containing at least one shorting or shunt conductor.

In FIG. 2 schematically shows an example where in one part of the card, separated by a line for dividing the card into fragments, the smart card contains the active main RFID tag, and in the other part of the card an additional RFID tag.

In FIG. Figure 3 shows an example when a short-circuit or shunt conductor passes through a fragment of a card that does not contain RFID tags.

In FIG. 4 shows an example of a smart card made of two layers with the possibility of separating fragments in layers.

In FIG. 5 shows an example of a line for dividing a map into fragments in the form of a broken curve.

In FIG. 6 shows an example of a card, where a fragment of the card is made with a structural element passing through an adjacent fragment and designed to break the conductor when separating the fragments.

In FIG. Figure 7 shows an example of a card where the antenna of the active main RFID tag passes through two fragments of the card so that in the normal unbroken state of the card, the antenna is in working contact, and in the state of the separated fragment with the main RFID tag, this RFID tag loses its functionality. In FIG. 8 schematically illustrates a possible example of a contactless smart card in which the smart card contains at least two additional RFID tags.

In the drawings: 1 — main substrate, 2 — RFID tag antenna located on the substrate; 3 - the main fragment of the map; 4 - microchip; 5 - shunt circuit (here in the form of a closing conductor); 6 - detachable fragment of a smart card; 7 - a line for dividing a smart card into fragments, 8 - an additional RFID tag, 9 - a line for separating a fragment of a smart card that does not contain RFID tags, 10 - a fragment of a smart card that does not contain RFID tags, 11 - an additional substrate ( separable layer) smart cards.

Utility Model Implementation

A contactless smart card can be made in the form of a substrate with an RFID tag located on it (an antenna and a microchip connected to it) or more than one RFID tag.

The card is made of a homogeneous laminated or composite material, plastic, paper (cardboard) or any material that meets the requirements of existing standards, may consist of layers of different or homogeneous materials. A card that is structurally unified under normal use can be divided into two or more parts. The card is divided into parts by mechanical separation of the card fragments by breaking off, tearing, cutting, separating one or more layers of the card or the like, while the design of the card allows the fragments to be separated along the agreed line with sufficient accuracy to achieve the claimed result. To simplify the separation of map fragments along the agreed dividing line, grooves, perforations, notches, card thickness differences, layer boundaries, material boundaries, boundaries of structural elements, internal cavities, and other material stress concentrators can be created along the fragments. For cards that are split into pieces by cutting (preferably cardboard or soft plastic), the line of separation may be indicated by a marking on the card body. The procedure for separating fragments, the location of the fragments to be separated, the location of the card dividing line can be communicated to the user with instructions for using the card without corresponding marking on the card.

The card contains the main RFID tag in the active state with the main identification code and one or more additional RFID tags in the inactive state with additional identification codes that differ from the main identification code. The main RFID tag in the active state, falling within the range of the working RFID reader, generates a response radio signal with the main identification code in the operating frequency range with a power sufficient for the reader to receive, the additional RFID tag in the inactive state, falling within the range of the reader, does not generate a response radio signal with an additional identification code in the operating frequency range with a power sufficient for reception by the reader.

Additional RFID tags have a shunt circuit that closes the terminals of the antenna or shunts all or part of the turns of the antenna, with a partially electrical conductor or conductive connection located on a detachable portion of the smart card. Alternatively, the terminals of the shunt circuit are connected to the deactivating outputs of the chip of the additional RFID tag, as the deactivating outputs are the conclusions of the integrated circuit of the additional RFID tag, in the closed state, in accordance with the chip topology, disabling the signal generation function of the additional RFID tag. The shunt circuit connected to the antenna turns of the additional RFID tag or to the deactivating terminals of the chip of the additional RFID tag is made in the form of an electrical conductor or the electrical conductor is included in the shunt circuit of the additional RFID tag so that in the condition of a broken contact of this conductor, the shunt circuit of the additional RFID tags are in a broken contact state. The conductor or conductive connection is made in such a way that when separating the corresponding fragment of the card, the connection is broken, the shunt circuit is in a state of broken contact. A detachable fragment of a smart card with a conductive connection can be made in any part of the card, for example, at the extreme or in the central parts of the smart card.

Breaking the conductive connection, shorting or shunting all or part of the antenna turns or deactivating through special outputs a chip of an additional RFID tag that does not previously work, previously unreadable in the operating frequency range, the RFID tag of the card turns into an activated RFID tag with an additional identification code, read adapted for this reader at the operating frequency. This solution allows the use of a detachable fragment with an additional RFID tag as an activated RFID identifier with an additional identification code.

A variant of the design of a smart card with a non-deactivated main RFID tag when splitting fragments can be a design where the main RFID tag is located within the same fragment of cards with an additional RFID, the main and additional RFID tags use different encoding schemes for data transmission or different operating frequency ranges. This option allows you to use a detachable fragment with an additional RFID tag as an activated RFID identifier with an additional identification code in cases where multi-mode RFID readers are used in automated identification systems, which are capable of reading and processing various types of RFID tags with different coding schemes, different operating frequency ranges, while the main RFID tag remains active, and in addition to the code for the additional tag, the system can also record the main metric code and. For systems where readers, by their technical characteristics, may not separate the codes of two simultaneously active tags - the primary and secondary, it is advisable to use the design of a card with a deactivated primary RF tag. The antenna of the active main RFID tag passes through two adjacent fragments of the card so that in the normal undestroyed state of the card, the antenna is in the state of working contact, and in the state of the separated indicated adjacent fragments, the antenna is in the state of broken contact, while the characteristics of the antenna are changed so that the main An RFID tag falling within the range of a working RFID reader does not generate a response radio signal necessary for the reader to receive power, and the main RFID tag loses its working ability spine. The main tag is deactivated by separating the fragment with the main RFID tag and breaking the antenna circuit of the main RFID tag or by breaking the shunt circuit that closes or shunts the deactivating outputs of the chip of the main RFID tag (as deactivating, use the conclusions of the integrated circuit of the main RFID tag in a closed the state in accordance with the topology of the integrated circuit including the function of generating the signal of the main RFID tag, and in the state of the broken contact of the shunt circuit of the main RFID tag, the gene radio basic RFID-tag signal).

The shunt circuit connected to the deactivating terminals of the chip of the main RFID tag can be made in the form of an electrical conductor or the electrical conductor is included in the shunt circuit of the main RFID tag so that in the condition of a broken contact of this conductor, the shunt circuit of the main RFID tag is in a state torn contact. The conductive connection is separated mechanically, i.e. there is a mechanical activation of new smart card features.

The first embodiment of the claimed solution is based on the fact (see Fig. 1) that the smart card has lines for dividing the card into fragments (the main part 3, containing the main, additional RFID tags and the detachable part 6 of the card), contains on the substrate 1 an additional RFID tag 8 with a chip 4 and antenna 2 having at least one shunt circuit consisting of a closing conductor 5. This conductor 5 is an electrical conductor connected in contact with antenna 2 of an additional RFID tag 8, or an integral connected to the terminals microchip additional RFID tags 8, structurally connected to the card on the substrate 1. The sections of the conductor 5 pass through two adjacent fragments 3 and 6 of the card so that in the normal non-destroyed state of the card, this conductor 5 is in the state of working contact, and in the state of the separated fragment 6, this conductor is in a broken contact state. In this case, the additional RFID tag 8 in the state of the working contact of the closing or shunt conductor 5 is made in an inactive state, and in the state of a broken contact of this conductor has an active state as an additional RFID tag.

The device can be implemented in such a way (see Fig. 2, Fig. 3) that in one part of the card, separated by a dividing line 7 of the card into fragments 3 and 6, contains the active main RFID tag, and in the other part of the card an additional RFID tag 8. This can be implemented in two ways. In the first case, the option can be used when the shunt circuit, consisting of the closing conductor 5, passes through the third fragment of the card 10 (Fig. 3), which has its own separate line of separation 9 with the fragment 6 of the card. Moreover, if the dividing line 7 is not on the card, then in one part covering fragments 3 and 6, the card contains the active main RFID tag and additional RFID tag 8, and part of the shunt conductor 5 passes through the other part of the card 10.

The second method implies (see Fig. 4, Fig. 5) that the sections of the electrical conductor 5 are made in two layers of the card (on the main substrate 1 and the additional substrate 11) connected to each other. In this case, the separation of the conductor 5 and the unlocking of the additional RFID tag 8 can be carried out so that the line for dividing the card into fragments runs along the boundary of the plane of contact of the layers (along the perimeter of the card) and is between two connected layers 1 and 11.

Technically, the sections of the electrical conductor 5 can then pass through adjacent fragments of the card through the line 7 dividing the card into fragments, if it is made, for example, in the form of a broken curve (see Fig. 5), or along the line 7 dividing the card into fragments (see Fig. 6), for example, if at least one fragment (here fragment 3) is made with one or more structural elements 12 protruding in the direction of the adjacent fragment 6, covering the conductor 5 of the shunt circuit, passing along the separation line 7 of the fragments, or inextricably connected to this conductor. Conductor 5 (see Fig. 6) from contact with one of the terminals of antenna 2 of the additional RFID tag 8 passes along fragment 6, then along separation line 7, then through element 12 of fragment 3, then again along separation line 7 and along fragment 6 fed to the second terminal of antenna 2 of an additional RFID tag. When separating fragments, the structural element 12 breaks the conductor 5 of the shunt circuit, activating an additional RFID tag 8.

Lines 7 and 9 of dividing a map into fragments can be performed in any way, for example: in the form of a line of breaking or breaking, or tearing, or notching, or cutting, or perforating, or changing the thickness of the map, or the boundaries of materials, or the boundaries of structural elements, or internal cavities, or boundary lines of contact of layers. The location of the separation lines on the map may not be marked, in this case, their location, as well as the location of the fragments to be separated, the order of separation of fragments can be communicated to the user with instructions for using the map.

It is also possible (see Fig. 7) that the antenna 2 of the active main RFID tag passes through two fragments 3 and 6 of the card so that in the normal non-destroyed state of the card, antenna 2 is in the working contact state, and in the state of the separated fragment with the main RFID - with a card tag along the separation line 7, this RFID tag loses its working capacity at the operating frequency. In this case, the additional RFID tag 8 on the contrary, there is a working state. This implementation of the smart card allows, when dividing it into fragments, to deactivate the main RFID tag and activate the additional RFID tag 8.

The second implementation option (see Fig. 8) of the solution is based on the fact that the smart card, in addition to the active main RFID tag, contains at least two additional RFID tags 8, each of which has at least one shunt circuit, which is an electrical conductor or a conductive connection comprising at least one electrical conductor so that in the state of a broken contact of this conductor, the bypass circuit is in a state of broken contact. The electrical conductor 5 is connected in contact with the antenna 2 of the corresponding additional RFID tag 8, or connected to the terminals of the integrated circuit 4 of the corresponding additional RFID tag 8. The sections of the electrical conductors 5 pass through two adjacent fragments 3 and 6 of the card so that in the normal non-destroyed state of the card these conductors 5 are in the state of working contact, and in the state of the separated fragment along the separation line 7, these conductors are in the state of broken contact. Moreover, in one fragment of the card, separated by a line 7 of dividing the card into fragments, the active main RFID tag and one of the additional RFID tags 8 may be contained.

Each of the additional RFID tags 8 in the working contact state of the corresponding closing or shunt conductor 5 is made in an inactive state, and in the broken contact state of this conductor 5 has an active state as an additional RFID tag 8.

At the same time, the main RFID tag, on the contrary, has an inoperative state, because its antenna 2 or part of the antenna turns passes through the dividing line 7 of the card into fragments, or along this line (see Fig. 6). In the state of the separated indicated adjacent fragments, the antenna is in a broken contact state, while the characteristics of the antenna are changed so that the main RFID tag, falling within the range of the working RFID reader, does not generate a radio signal response necessary for the reader to receive power and the main RFID tag loses working capacity. In other words, the antenna 2 of the active main RFID tag passes through two fragments of the card so that in the normal unbroken state of the card, the antenna is in the working contact state, and in the state of card breakdown, this RFID tag loses its functionality. There are other possible arrangements for the antenna 2 of the active main RFID tag, in which the antenna has a complex configuration with access to the second additional layer of the substrate 11 or the shunt circuit of the main RFID tag has a complex configuration with the output to the second additional layer of the substrate 11 and deactivation of the main RF tag is carried out not by rupture of the antenna, but by rupture of the circuit shunting the deactivating outputs of the chip of the main RFID tag (as deactivating, the conclusions of the integrated circuit of the main RFID tag are used, as and the broken contact of this shunt circuit of the main RFID tag, in accordance with the topology of the microcircuit, disabling the function of generating a signal with the code of the main RFID tag). Variants are possible where parts of the shunt circuits of additional RFID tags can be made in two layers of the card connected to each other, by analogy with FIG. 4, FIG. 5. These described examples and other methods (not shown in the drawings) may have many implementation options that provide the technical result of the claimed solution. For example, this can be realized, including so that in one fragment of the map, separated by a line for dividing the map into fragments, the active main RFID tag may be contained, and additional RFID tags may not be contained. In the second and first embodiments, the sections of the electrical conductor can pass through adjacent card fragments along the line for splitting the card into fragments if, for example, one card fragment is made with one or more structural elements protruding in the direction of the adjacent fragment, covering the shunt circuit conductor passing along the line of separation of fragments, or inextricably connected to this conductor and when separating fragments, such structural elements break the conductor of the shunt circuit.

The technical result of expanding the functionality of a contactless smart card, the activation of which occurs at a time necessary for the user at his request, is ensured by the fact that the above-described options for implementing the technical solution form the working conditions of the smart card in such a mode that the main card is deactivated when the card fragments are separated The RFID tag is activated and an additional or two additional ones, or when separating fragments of the card, together with the active main RFID tag, is activated earlier than update themselves more RFID-label or more. These conditions allow technically to carry several functions in one smart card:

- primary and secondary, activated in the event of a user circumstance (for example, in an emergency, alarm situation or fire);

- the main and two or more additional ones that are activated in the event of a user circumstance (for example, in an emergency, terrorist threat, alarm situation or fire), while the main function is lost forever.

It is also possible to use a smart card as a means of payment in transport, museums and cinemas, where the application of the claimed solution excludes the possibility of repeatedly debiting funds due to the unintentional repeated application of a ticket (card) based on the stated solution to the reader, the turnstile validator.

For example, if each pass through the turnstile will work only at the next cracking of a fragment of the smart card and the activation of the next additional RFID tag, each of which gives 1 pass, the user directly on the card itself sees visually how many passages it has and accidental use is excluded.

It is also possible to use a smart card as a hidden alarm. Access to the panic button in the event of a terrorist danger, robbery or gangster attack may be limited or absent, and the user always has access to the smart card. Smart card cracking activates the alarm mode if the RFID reader is active in the entire room or in the place where the organization’s employee who has been attacked is secretly holding a fragment of the card to the nearest reader is also more likely than calling a security service using telephone.

Claims (18)

1. A non-contact identification smart card containing an active main RFID tag having a line for dividing the card into fragments, characterized in that it contains an additional RFID tag, which has a shunt circuit, which is a conductive connection using an electrical conductor, connected in contact with an additional RFID tag, and sections of this shunt circuit pass through two adjacent fragments of the card and are structurally connected to the card so that in the normal non-destroyed state of the card this shunt the circuit is in a state of working contact, and in the state of separated indicated adjacent fragments, this shunt circuit is in a state of broken contact, while the additional RFID tag in the state of the working contact of the shunt circuit of an additional RFID tag is in an inactive state, and in a state of broken contact The shunt circuit has an active state as an additional RFID tag. 2. The contactless smart card according to claim 1, characterized in that the antenna of the active main RFID tag passes through two adjacent fragments of the card so that in the normal non-destroyed state of the card, the antenna is in a working contact state, and in the state of the indicated adjacent adjacent fragments, the antenna is in a state of broken contact, while in the state of broken contact of the antenna, the main RFID tag, falling within the range of a working RFID reader, does not generate a response radio signal necessary for reception by the reader power and the main RFID tag loses performance. 3. The contactless smart card according to claim 1, characterized in that the main RFID tag has at least one shunt circuit, which is an electrical conductor or conductive connection, containing at least one electrical conductor connected in contact with the deactivating terminals of the main integrated circuit RFID tags and sections of this shunt circuit pass through two adjacent fragments of the card and are structurally connected to the card so that in the normal unbroken state of the card, this shunt circuit is in condition the working contact, and in the state of the indicated indicated adjacent fragments, this shunt circuit is in the broken contact state, while the main RFID tag in the working contact state of the shunt circuit of the main RFID tag is in the active state, and in the broken contact state of this shunt circuit inactive state. 4. The contactless smart card according to claim 1, characterized in that the active primary RFID tag and an additional RFID tag are located in different fragments of the card. 5. The contactless smart card according to claim 1, characterized in that it has at least one fragment that does not contain RFID tags, and a portion of the shunt circuit of the additional RFID tag or a portion of the shunt circuit of the main RFID tag or sections passes through this fragment of the card both shunt circuits. 6. The contactless smart card according to claim 1, characterized in that the active primary RFID tag and an additional RFID tag are located within one of the fragments of the card. 7. A contactless smart card according to claim 1, characterized in that the lines for dividing the card into fragments are made in the form of lines of breaking, or breaking, or tearing, or cutting, or notching, or punching, or changing the thickness of the card, or the borders of materials, or the boundaries of structural elements, or internal cavities, or boundary lines of contact of the layers, while the design of the card provides the ability to separate fragments along the agreed line with acceptable accuracy. 8. A contactless smart card according to claim 1, characterized in that at least one fragment of the card is made with one or more structural elements protruding in the direction of the adjacent fragment, covering at least one electrical conductor from among the electrical conductors of the shunt circuits of the main and additional RFID tags, or inextricably connected to this conductor and designed to rupture this conductor when separating fragments, while sections of this electrical conductor pass through VA adjacent map fragments along the line of dividing the map into fragments. 9. A contactless smart card according to claim 1, characterized in that the card fragments are made in the form of card layers connected to each other, with the possibility of separating the fragments in layers, while sections of one or more conductors from among the electrical conductors of the shunt circuits of the main and additional RFID tags are made in two or more layers of the card. 10. The contactless smart card according to claim 1, characterized in that it contains at least two additional RFID tags, each having at least one shunt circuit, which is an electrical conductor or a conductive connection containing at least one electrical conductor connected by contact with the antenna of the corresponding additional RFID tag, or connected in contact with the terminals of the integrated circuit of the corresponding additional RFID tag, and parts of this shunt circuit pass through two adjacent fragments of cards s and are structurally connected to the card so that in the normal unbroken state of the card, this shunt circuit is in a state of working contact, and in the state of separated indicated adjacent fragments, this shunt circuit is in a state of broken contact, with each of the additional RFID tags in a state of working the contact of the shunt circuit of this additional RFID tag is in an inactive state, and in the state of a broken contact of this shunt circuit has an active state as an additional RFID Christmas trees. 11. The contactless smart card according to claim 10, characterized in that the antenna of the active main RFID tag passes through two adjacent fragments of the card so that in the normal non-destroyed state of the card, the antenna is in a working contact state, and in the state of the indicated adjacent adjacent fragments, the antenna is in a state of broken contact, in which the main RFID tag, falling within the range of a working RFID reader, does not generate a response radio signal necessary for the reader to receive power and the main RFID tag loses botability. 12. The contactless smart card according to claim 10, characterized in that the main RFID tag has at least one shunt circuit, which is an electrical conductor or conductive connection containing at least one electrical conductor connected in contact with the deactivating terminals of the main integrated circuit RFID tags and sections of this shunt circuit pass through two adjacent fragments of the card and are structurally connected to the card so that in the normal unbroken state of the card, this shunt circuit is in melting of the working contact, and in the state of the indicated indicated adjacent fragments, this shunt circuit is in the state of broken contact, while the main RFID tag in the state of the working contact of the shunt circuit of the main RFID tag is in the active state, and in the state of the broken contact of this shunt circuit inactive state. 13. The contactless smart card according to claim 10, characterized in that in one fragment of the card contains the active main RFID tag and does not contain additional RFID tags. 14. A contactless smart card according to claim 10, characterized in that it has at least one fragment that does not contain RFID tags, through which passes a portion of one or sections of several shunt circuits from among the shunt circuits of the main and additional RFID tags. 15. The contactless smart card according to claim 10, characterized in that the active primary RFID tag and one of the additional RFID tags are located within one of the fragments of the card. 16. The contactless smart card according to claim 10, characterized in that the lines for dividing the card into fragments are made in the form of lines of breaking or breaking, or tearing, or cutting, or notching, or punching, or changing the thickness of the card, or the borders of materials, or the boundaries of structural elements, or internal cavities, or boundary lines of contact of the layers, while the design of the card provides the ability to separate fragments along the agreed line with acceptable accuracy. 17. The contactless smart card according to claim 10, characterized in that at least one fragment of the card is made with one or more structural elements protruding in the direction of the adjacent fragment, covering at least one electrical conductor from among the electrical conductors of the shunt circuits of the main and additional RFID tags or inextricably connected to this conductor and designed to rupture this conductor when separating fragments, while sections of this electrical conductor pass through of adjacent map fragments along the line of dividing the map into fragments 18. A contactless smart card according to claim 10, characterized in that the card fragments are made in the form of card layers connected to each other with the possibility of separating fragments in layers, while sections of one or more conductors from among the electrical conductors of the shunt circuits of the main and additional RFID -tags made in two or more layers of the map.

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