DE102020114528B3 - Smart card sleeve, method of using a smart card sleeve, smart card sleeve and smart card system - Google Patents

Abstract

A chip card case (101) is provided, which has a case body (106) with a chip card receiving area (106A) for receiving a chip card and a booster antenna arranged on or in the case body (106) with at least one coupling area (108K) for inductive coupling to an antenna of the chip card in the case of a chip card (102) accommodated in the chip card receiving area (106A).

Description

The invention relates to a chip card cover, a method for using a chip card cover and a chip card system.

Many users today have multiple smart cards (especially contactless) for different purposes: bank cards, credit cards, access cards for work and/or a leisure facility, season tickets for public transport, etc.

For at least some applications it might be useful to provide a smart card with multiple uses.

A challenge can be that contactless chip cards use two different technologies and standards, namely ISO 14443 and ISO 15693.

the JP 2003 - 180 434 A discloses a card case that can hold a thin, rectangular card in plate form such that the card protrudes from the card slot.

the JP 2005 - 332 015 A discloses a card case structure of a card case body corresponding to a front side or a back side of the contactless IC card, in which an IC chip and a communication antenna are built.

the WO 2012 / 028 299 A1 discloses a carrier of a chip module for a portable data carrier, on the first side of which an integrated circuit and a coil-shaped antenna are arranged, and on an opposite second side metallic contact surfaces for contactless or contact-based data and/or energy transfer between an external device and the integrated circuit

the US 2018 / 032 854 A1 discloses a smart card module comprising a carrier having a first side and an opposite second side, a chip disposed over the carrier, the chip having a first chip contact, first and second antenna contacts formed over the first side, a metal-free Area formed over the first side between the first antenna contact and the second antenna contact, the metal-free area extending between a first edge portion and a second edge portion of the carrier, and a first chip connection electrically connecting the first chip contact to the first antenna contact, wherein the first die pad is at least partially disposed over the second side in an area opposite the metal-free area.

the JP 2007 - 133 781 A discloses a card case for storing a card including an information identification element connected to an antenna to be communicable thereby, the card case being provided with a connection part having a plurality of connection terminals, each of the connection terminals information identification element being connectable.

the U.S. 2016/0 267 466 A1 discloses a device that stores multiple identifiers dedicated to specific purposes, with the multiple transaction tokens residing on different parts of a user device. Each transaction token can be compatible for use with a transaction channel.

the U.S. 7,044,388 B2 discloses a non-contact IC card in which there are two separate combinations of an IC chip and an antenna coil coupled to that chip.

A smart card sleeve according to claim 1, a smart card system according to claim 10, a method of using a smart card sleeve according to claim 15 and a smart card sleeve according to claim 17 are provided. Further embodiments are given in the dependent claims.

In various exemplary embodiments, an antenna (which can be coupled to a chip and designed, for example, as a so-called coil-on-module) and an (inductively coupling) booster antenna are arranged on separate carriers that can be mechanically coupled. The antenna (or the chip module with the antenna) and the coupling area of the booster antenna can be positioned on their respective carriers in such a way that there is also an inductive coupling of the coupling area of the booster antenna to the antenna for at least one mechanically coupled position. so that the two carriers are able to fulfill a function of a contactless chip card in the coupled state.

In various exemplary embodiments, one of the carriers can be a chip card and the other carrier can be a chip card cover with a receiving area for the chip card.

In various exemplary embodiments, the chip module with the antenna can be arranged on or in the chip card, and the booster antenna with the coupling area can be arranged on or in the cover.

In various exemplary embodiments, the booster antenna with the coupling area can be arranged on or in the chip card, and the chip module with the antenna can be arranged on or in the sleeve.

In various exemplary embodiments, a sleeve for a chip card with a coil-on-module chip module is provided (as a dual-interface module with a contact-based interface, e.g. with 6 or 8 pins and a contactless interface, or as a contactless module with only contactless interface). The cover can be set up to activate the contactless interface using a booster antenna integrated into the cover.

Exemplary embodiments of the invention are shown in the figures and are explained in more detail below.

• 1A und 1B jeweils eine Veranschaulichung einer Nutzung eines Chipkartensystems gemäß verschiedenen Ausführungsbeispielen, welches eine Chipkartenhülle gemäß verschiedenen Ausführungsbeispielen und eine Chipkarte aufweist;
• 2 eine Chipkarten-Hülle gemäß verschiedenen Ausführungsbeispielen und eine Chipkarte, welche zum Bilden eines Chipkartensystems zusammen mit der Chipkarten-Hülle eingerichtet ist;
• 3 eine Chipkarten-Hülle gemäß verschiedenen Ausführungsbeispielen und eine Chipkarte, welche zum Bilden eines Chipkartensystems zusammen mit der Chipkarten-Hülle eingerichtet ist;
• 4A und 4B jeweils eine Chip-Kartenhülle gemäß verschiedenen Ausführungsbeispielen und eine Karte, welche zum Bilden eines Chipkartensystems zusammen mit der Chip-Kartenhülle eingerichtet ist;
• 5 eine Chipkartensystem-Einrichtung gemäß verschiedenen Ausführungsbeispielen; und
• 6 ein Flussdiagramm eines Verfahrens zum Verwenden einer Chipkarten-Hülle gemäß verschiedenen Ausführungsbeispielen.

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• 1A and 1B in each case an illustration of a use of a chip card system according to various exemplary embodiments, which has a chip card shell according to various exemplary embodiments and a chip card;
• 2 a chip card shell according to various exemplary embodiments and a chip card which is set up to form a chip card system together with the chip card shell;
• 3 a chip card shell according to various exemplary embodiments and a chip card which is set up to form a chip card system together with the chip card shell;
• 4A and 4B in each case a chip card shell according to various exemplary embodiments and a card which is set up to form a chip card system together with the chip card shell;
• 5 a chip card system device according to various exemplary embodiments; and
• 6 a flowchart of a method for using a smart card shell according to various embodiments.

In the following detailed description, reference is made to the accompanying drawings that form a part hereof, and in which is shown by way of illustration specific embodiments in which the invention may be practiced. In this regard, directional terminology such as "top", "bottom", "front", "back", "front", "rear", etc. is used with reference to the orientation of the figure(s) being described. Because components of embodiments can be positioned in a number of different orientations, the directional terminology is used for purposes of illustration and is in no way limiting. It is understood that other embodiments may be utilized and structural or logical changes may be made without departing from the scope of the present invention. It is understood that the features of the various exemplary embodiments described herein can be combined with one another unless specifically stated otherwise. The following detailed description is, therefore, not to be taken in a limiting sense, and the scope of the present invention is defined by the appended claims.

Within the scope of this description, the terms "connected", "connected" and "coupled" are used to describe both a direct and an indirect connection, a direct or indirect connection and a direct or indirect coupling. In the figures, identical or similar elements are provided with identical reference symbols, insofar as this is appropriate.

For elements that can occur in multiple versions, such as antennas or chip modules, and which are distinguished from one another by the respective reference number, the reference number is sometimes used in the description without the suffixed digits are used, even though the reference number without the suffixed digit has been omitted in the figures to save space.

1A and 1B each show an illustration of a use of a chip card system 100 according to various exemplary embodiments. Each of the chip card systems 100 has a chip card shell 101 according to various exemplary embodiments and a chip card 102 . 2 and 3 each show a chip card shell 101 according to various exemplary embodiments and a chip card 102 which is set up to form a chip card system 100 together with the chip card shell 101. 5 shows a chip card system device 500 according to various exemplary embodiments, which has a chip card system 100 and a reader 550.

In various exemplary embodiments, the chip card sleeve 101 can have a sleeve body 106 with a chip card receiving area 106A for receiving a chip card 102 .

The chip card receiving area 106A can be located, for example, as a hollow space between two layers of the case body 106 . The two layers can form a front and a back of the cover body 106, which can be attached to one another or can be formed together. See the examples in 1A until 5 . The case body 106 can be formed, for example, similar to chip card cases known in the prior art for the mechanical protection of chip cards 102, with the chip card case 101 having special features which are explained here.

The case body 106 can be formed from an electrically insulating material, for example a plastic material, for example a thermoplastic material, in various exemplary embodiments. In various exemplary embodiments, the cover body can have a plurality of (e.g. shaping) materials, for example formed as a layered structure or have different materials in different surface areas.

For example, the case body 106 may include a window 110, which may be formed of a transparent material, while the other portions of the case body 106 may be formed of an opaque or translucent (but not transparent) material. Alternatively, the window 110 may be formed as a through hole in the front of the case body 106 .

In various exemplary embodiments, the sleeve body 106 with the chip card receiving area 106A can be formed as an essentially single-layer structure with a chip card fastening structure, for example clips that grip the chip card 102 from edge areas (not shown).

The chip card sleeve 101 can be formed in such a way that it completely or essentially completely accommodates the chip card 102 . This is an example in 1A , 1B and 2 shown.

The chip card sleeve 101 can be formed in such a way that it only partially accommodates the chip card 102 . This is an example in 3 shown, with the portion of the chip card 102 to be accommodated in the chip card cover 101 being indicated in dashed lines. The partial areas, which differ depending on the direction of insertion and which protrude from the chip card sleeve 101 after the chip card 101 has been received in the chip card receiving area 106A, are indicated with a solid line.

Similarly, a chip card 102 can be clamped in a single-layer chip card sleeve 101 covering only part of the chip card 102 .

A chip card sleeve 101 that does not completely cover or accommodate chip card 102 can be advantageous, for example, if chip card 102 is designed as a so-called dual-interface chip card, which is set up for contactless operation and for contact-based operation is. The chip card 102 typically has a contact-based interface 330 for contact-based operation. It may be necessary to insert the chip card 102 into a contact-based reader far enough for contact areas of the contact-based interface 330 on the chip card 102 (typically they are part of a chip module) to contact mating contacts in the reader. This is practically impossible or hardly possible with a chip card 102 that is completely covered by a chip card shell 101 , so that the chip card 102 would have to be removed from the chip card shell 101 . Accordingly, a chip card cover 101, which leaves an area of the chip card 102 that extends from an edge of the chip card 102 to at least the contact surfaces, is advantageous because this enables the use of the contact-based interface 330 without the chip card 102 being removed from the Chip card case 101 needs to be removed.

The chip card sleeve 101 can have a booster antenna 108 arranged on or in the sleeve body 106 with at least one coupling area 108K for inductive coupling to an antenna 112 of the chip card 102 when a chip card 102 is accommodated in the chip card receiving area.

By means of the inductive coupling between the coupling area 108K and the antenna 112 of the chip card 102, a contactless function can be provided for contactless communication with a reading device 550 (see 5 ), for example by means of near field communication (NFC). For example, the reader 550 can enable a payment function, grant access to a restricted area, etc.

In various exemplary embodiments, the antenna 112 can be connected to a chip, for example as part of a chip module 104 which can have the chip connected to the antenna 112 .

During or after the formation of the chip card body 106, a booster antenna 108 can be arranged in or on it, for example laminated in, laid, structured from a metal layer, or in any other way known for forming booster antennas. For maximum coupling between the coupling region 108K and the antenna 112 of the smart card 102, the booster site 108 can be arranged to be as close to the antenna 112 as possible. For example, the booster antenna 108 can be arranged on or in a side of the chip card body 106 facing the chip card receiving area 106A.

In various exemplary embodiments, the coupling area 108K can be arranged laterally centrally in such a way that the inductive coupling takes place with any orientation of the chip card 102. In that case it may be necessary for the antenna 112 to be arranged centrally in the chip card 102 as well.

In various exemplary embodiments, the coupling region 108K can be arranged on a central axis A (longitudinal or transverse axis) of the chip card sleeve 101 such that inductive coupling to the antenna 112 (ie to the same antenna 112) is only possible in two predefined orientations out of four possible orientations of the chip card 102 takes place.

Such an arrangement is in 1A and 1B shown.

The chip card 102 used there has two antennas 112-1, 112_2, both of which are embedded in the chip card 102 as part of a chip module 104_1 or 104_2.

The use of multiple antennas/chip modules is explained in more detail below. Due to the arrangement of the coupling area 108K on the longitudinal axis of the chip card cover 101 (and the arrangement of the antennas 112_1, 112_2 on the longitudinal axis of the chip card 102), there is an inductive coupling between one (the second) of the two antennas 112_2 and the coupling area 108K , when the chip card 102 is introduced into the chip card receiving area 106A in the insertion direction shown. In addition, an inductive coupling can occur between one (the second) of the two antennas 112 2 and the coupling area 108K when the chip card 102 is rotated about the longitudinal axis and then introduced into the receiving area 106A. Further orientations of the chip card 102 do not cause any inductive coupling between the coupling area 108K of the chip card cover 101 and the antenna 112_2 of the chip card 102 (however with the antenna 112_1).

In various exemplary embodiments, the coupling region 108K can be arranged away from the central axis A in such a way that the inductive coupling with a specific antenna 112 arranged on the chip card 102 only takes place in a predefined orientation of four possible orientations of the chip card 102 . Such an example is in 2 shown. There, the coupling area 108K is arranged in a corner of the chip card case 101, and a coupling of the coupling area 108K with one and the same of the (in this exemplary embodiment four) antennas 112_1, 112_2, 112_3, 112_4 can only be possible with a single insertion direction.

In each of the other directions of insertion, the coupling can take place with one of the other antennas 112_1, 112_2, 112_3, 112_4. For example, in 2 when the chip card 102 is arranged in the chip card receiving area 106A in the orientation that is shown in the middle, the first antenna 112_1 with the coupling area 108K. When the chip card 102 is rotated through 180° within the card plane, the second antenna 112_2 couples to the coupling area 108K.

When a chip card 102 is rotated (about a central axis A in the longitudinal direction), in 2 orientation shown below, the third antenna 112_3, and in the case of the chip card 102 within the card plane by 180°, the fourth antenna 112_4 couples to the coupling area 108K.

If fewer than four antennas 112 are provided in the arrangement of the coupling region 108K away from the central axis A on the chip card 102, there can be at least one inactive orientation in which mechanical protection of the chip card 102 is provided by the chip card sleeve 101 without a contactless function of the chip card 102 is provided by the inductive coupling between the coupling region 108K and the antenna 112 or one of the antennas 112.

In particular, if there are several antennas 112 on the chip card 102, it may be necessary to give a user an indication of which of the antennas 112 couples with the coupling area 108K in a selected arrangement of the chip card 102 in the chip card receiving area 106A, ie which of the functions of the chip card 102 is active.

This can be made possible in various exemplary embodiments by means of an inscription or identification, for example an imprint, on the chip card 102 and a corresponding transparent subarea 110 (also referred to as a window) in the chip card case 101. In 1A until 4B Figure 12 illustrates how the active chip is indicated using the label and window together.

In various embodiments, the chip card shell 101 can also at least have a shielding element (not shown), the shielding element being able to be arranged in the chip card sleeve 101 in such a way that the shielding element covers the antenna 112 in at least one of the possible orientations of the chip card 102 .

4A and 4B each show a chip card shell 401 according to various exemplary embodiments and a card 402 which is set up to form a chip card system 400 together with the chip card shell 401.

As stated in the introduction, it can be an aspect of various exemplary embodiments that the antenna 112 and the booster antenna 108 with the coupling area 108K are arranged on separate carriers 103, 106 that can be mechanically coupled, with the antenna 112 and the coupling area 108K being the booster Antenna 108 can be positioned on their respective carriers 103, 106 so that there is also an inductive coupling of the coupling region 108K of the booster antenna 108 with the antenna 112 for at least one mechanically coupled position, so that the two carriers 103, 106 in the coupled State are able to fulfill a function of a contactless chip card.

Accordingly, in various exemplary embodiments, the carriers 103, 106 can be swapped, clearly described: the antenna 112 (together with the chip connected to it; not shown individually, the chip is part of the chip module 104 in this exemplary embodiment) on or in the casing body 106 The chip card shell 401 can be arranged, and the booster antenna 108 with the coupling area 108K can be arranged on or in the card 402.

Accordingly, a chip card case 401 can be provided in various exemplary embodiments, which has a case body 106 with a card receiving area 106A for receiving a card 402, a chip arranged on or in the case body 106 and an antenna 112 electrically conductively connected to the chip. the chip card case 401 being set up for inductive coupling to a coupling area 108K of a booster antenna 108 of the card 402 accommodated in the card receiving area 106A.

A system 400 consisting of the chip card shell 401 and the card 402 can thus fulfill a function of a contactless chip card and be set up, for example, to communicate contactlessly with a contactless reader 550 . See 5 .

The above statements on the lateral position of the coupling area 108K or the antenna(s) 112, number of chips/antennas, etc. also apply mutatis mutandis to exemplary embodiments in which the coupling area 108K and the antenna 112 are swapped with regard to their respective carriers 103, 106 .

6 FIG. 6 is a flow diagram 600 of a method for using a smart card shell according to various embodiments.

The method includes inserting a chip card into a chip card receiving area of a case body of the chip card case (at 610) and inductively coupling a coupling area of a booster antenna arranged on or in the case body to an antenna of the chip card (at 620).

Some exemplary embodiments are summarized below.

Exemplary embodiment 1 is a chip card sleeve that has a sleeve body with a chip card receiving area for receiving a chip card and a booster antenna arranged on or in the sleeve body with at least one coupling area for inductive coupling to an antenna of the chip card at one in the chip card receiving area recorded chip card has.

Exemplary embodiment 2 is a chip card cover according to exemplary embodiment 1, with the coupling area being arranged centrally in such a way that inductive coupling takes place in any desired orientation of the chip card.

Exemplary embodiment 3 is a chip card cover according to exemplary embodiment 1, with the coupling area being arranged on a central axis in such a way that the inductive coupling only takes place in two predefined orientations of four possible orientations of the chip card.

Exemplary embodiment 4 is a chip card cover according to exemplary embodiment 1, with the coupling area being arranged away from the central axis in such a way that the inductive coupling only takes place with a predefined orientation of four possible orientations of the chip card.

Exemplary embodiment 5 is a chip card cover according to one of exemplary embodiments 1 to 4, the antenna being part of a contactless interface, for example a coil-on-module interface.

Exemplary embodiment 6 is a chip card cover according to one of exemplary embodiments 1 to 5, which is set up to completely or essentially completely cover the chip card.

Exemplary embodiment 7 is a smart card cover according to one of exemplary embodiments 1 to 6, which is set up to cover a first partial area of the smart card and leave a second partial area of the smart card uncovered.

Exemplary embodiment 8 is a chip card cover according to exemplary embodiment 7, with the second partial area of the chip card having a contact-based interface.

Exemplary embodiment 9 is a chip card sleeve according to one of exemplary embodiments 1 to 8, which also has at least one transparent partial area.

Exemplary embodiment 10 is a chip card sleeve according to one of exemplary embodiments 1 to 9, which also has at least one shielding element, the shielding element being arranged in the chip card sleeve such that the shielding element covers the antenna in at least one of the possible orientations of the chip card.

Exemplary embodiment 11 is a chip card system which has a chip card cover according to one of exemplary embodiments 1 to 10 and the chip card.

Exemplary embodiment 12 is a chip card system according to exemplary embodiment 11, the chip card having a contactless interface which has the antenna.

Exemplary embodiment 13 is a chip card system according to exemplary embodiment 11 or 12, the chip card having at least one further contactless interface with a further antenna, and each of the further contactless interfaces being able to be arranged in a further orientation of the chip card in the chip card shell in such a way that it inductively coupled to the coupling area.

Exemplary embodiment 14 is a smart card system according to any one of exemplary embodiments 11 to 13, the smart card further having a contact-based interface.

Exemplary embodiment 15 is a chip card system according to exemplary embodiment 14, the contactless interface and the contact-based interface being arranged separately from one another.

Embodiment 16 is a chip card system according to embodiment 14 or 15, wherein the chip card can be arranged in the chip card case in such a way that the contact-based interface is exposed.

Exemplary embodiment 17 is a smart card system according to exemplary embodiment 16 wherein the contact-based interface is exposed so that it can be plugged into a contact-based reader without the smart card shell.

Exemplary embodiment 18 is a method for using a chip card case, which includes inserting a chip card into a chip card receiving area of a case body of the chip card case and inductively coupling a coupling area of a booster antenna arranged on or in the case body with an antenna of the chip card .

Embodiment 19 is a method according to embodiment 18, further comprising communicating with a contactless reading device.

Exemplary embodiment 20 is a chip card case which has a case body with a card receiving area for receiving a card, a chip arranged on or in the case body and an antenna electrically conductively connected to the chip, the chip card case being set up for inductive coupling with a coupling area of a booster antenna of the card accommodated in the card receiving area.

Further advantageous configurations of the device result from the description of the method and vice versa.

Claims (17)

Smart card case (101) comprising: • a sleeve body (106) with a chip card receiving area (106A) for receiving a chip card (102); • a booster antenna (108) arranged on or in the cover body (106) with at least one coupling area (108K) for inductive coupling to an antenna (112) of the chip card (102) with a chip card accommodated in the chip card receiving area (106A). (102); and • at least one shielding element, the shielding element being arranged in the chip card sleeve (101) in such a way that the shielding element covers the antenna (112) in at least one of the possible orientations of the chip card (102). Smart card cover (101) according to claim 1 , wherein the coupling area (108K) is arranged centrally in such a way that the inductive coupling takes place in any orientation of the chip card (102). Smart card cover (101) according to claim 1 , wherein the coupling area (108K) on a cent ral axis (A) is arranged that the inductive coupling takes place only in two predefined orientations of four possible orientations of the chip card (102). Smart card cover (101) according to claim 1 , wherein the coupling area (108K) is arranged away from the central axis (A) in such a way that the inductive coupling takes place only in a predefined orientation of four possible orientations of the chip card (102). Smart card case (101) according to one of Claims 1 until 4 , wherein the antenna (112) is part of a contactless interface, for example a coil-on-module interface. Smart card case (101) according to one of Claims 1 until 5 , which is set up to cover the chip card (102) completely. Smart card case (101) according to one of Claims 1 until 5 , which is set up to cover a first portion of the chip card (102) and to leave a second portion of the chip card uncovered. Smart card cover (101) according to claim 7 , wherein the second portion of the chip card (102) has a contact-based interface (330). Smart card case according to one of Claims 1 until 8th , further comprising: at least one transparent portion (110). Chip card system, comprising: • a smart card case (101) comprising: • a sleeve body (106) with a chip card receiving area (106A) for receiving a chip card (102); • a booster antenna (108) arranged on or in the cover body (106) with at least one coupling area (108K) for inductive coupling to an antenna (112) of the chip card (102) with a chip card accommodated in the chip card receiving area (106A). (102); and • the chip card (102); • wherein the chip card (102) has a contactless interface which has the antenna (112); • wherein the chip card (102) has at least one additional contactless interface with an additional antenna (112_2), • wherein each of the further contactless interfaces can be arranged in a further orientation of the chip card (102) in the chip card shell in such a way that it inductively couples to the coupling area (108K); and • wherein the at least one coupling area (108K) is either arranged on a central axis (A) such that the inductive coupling only takes place in two predefined orientations of four possible orientations of the chip card (102), or is arranged off the central axis (A). that the inductive coupling takes place only in a predefined orientation of four possible orientations of the chip card (102). Chip card system according to claim 10 , wherein the chip card (102) further comprises a contact-based interface (330). Chip card system according to claim 11 , wherein the contactless interface and the contact-based interface (330) are arranged separately from each other. Chip card system according to claim 11 or 12 , wherein the smart card (102) in the smart card case (101) can be arranged so that the contact-based interface (330) is exposed. Chip card system according to Claim 13 wherein the contact-based interface (330) is exposed to be plugged into a contact-based reader without the smart card shell (101). Method for using a chip card case, comprising: • introducing a chip card into a chip card receiving area of a case body of the chip card case according to one of Claims 1 until 9 (610); and • inductively coupling a coupling area of a booster antenna arranged on or in the case body to an antenna of the chip card (620). procedure according to claim 15 , further comprising: communicating with a contactless reading device. Smart card case (401) comprising: • a case body (106) having a card receiving area (106A) for receiving a card (402); • a chip arranged on or in the case body (106); and • an antenna (112) electrically conductively connected to the chip; • wherein the chip card shell (401) is set up for inductive coupling to a coupling area (108K) of a booster antenna (108) of the chipless card (402) accommodated in the card receiving area (106A).

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