EP3815479A1

EP3815479A1 - Methods for manufacturing a roll medium for electronic components, a chip-card module and a chip card, and a medium for electronic components

Info

Publication number: EP3815479A1
Application number: EP19745194.1A
Authority: EP
Inventors: Christophe Mathieu
Original assignee: Linxens Holding SAS
Current assignee: Linxens Holding SAS
Priority date: 2018-06-15
Filing date: 2019-06-12
Publication date: 2021-05-05
Also published as: KR20210020099A; CN112335347B; SG11202012537RA; US11412620B2; FR3082696B1; WO2019239061A1; FR3082696A1; US20210251084A1; CN112335347A

Abstract

The invention relates to a method for manufacturing a flexible roll medium (10, 20) for supporting electronic components (14). Said method comprises a step of transferring, onto said flexible medium (10, 20), electronic components (14) made from an initial flexible roll substrate. For example, the electronic components (14) can be manufactured on an initial substrate having a width designed for densifying the manufacture of the components (14) on said initial substrate. Subsequently, each of the individual electronic components (14) are transferred onto the flexible support (10, 20), enabling, for example, a packaging that is better suited to be used with electronic components (14) than with the initial substrate, especially when said components must be integrated into a smart card (100). Thus, for example, the flexible support (10, 20) may be, or may comprise, a conductive or non-conductive adhesive (12, 23), which is used to attach, and possibly connect, each electronic component (14) to a smart card.

Description

Title of the invention: Methods of manufacturing a roll holder for electronic components, a smart card module and a smart card, as well as support for electronic components

The invention relates to the field of manufacturing electronic components to be integrated and connected in smart cards.

The electronic components concerned by the invention can be modules for smart cards (bank cards, transport subscription cards, identity cards, cards with subscriber identification module also called "SIM cards". "From the acronym of Subscriber Identification Module, etc.). These smart card modules can be:

contact modules for reading or writing information contained in one or more chips or memories integrated in the module itself or the card in which the module is integrated, such modules can for example correspond to ISO 7810,

- biometric control devices (fingerprint reader for example),

- visual cryptogram displays (CW type, or "Card verification value" in English),

- remote communication components (Bluetooth type for example),

- etc.

These electronic components or modules must be reliably fixed in a cavity in the card which receives them, and possibly connected to an antenna and / or a flexible printed circuit connecting electronic components and integrated into the body of the card. , for example between constituent layers thereof. These components can be transferred from one support to another using chip transfer techniques. An example of a technique of this kind is described for example in the document FR2613175A1.

The invention aims to improve the methods of manufacturing electronic components of this type and, possibly their integration, in cards and in particular smart cards. This object is at least partially achieved using a method of manufacturing a roll support for electronic components, in which

- we provide a flexible roll support that we unroll,

- at least one electronic component is supplied,

at least one electronic component is placed on an unwound part of the flexible support,

In addition, the flexible support comprises an adhesive material suitable for receiving and fixing an electronic component before transferring this electronic component to a smart card.

Indeed, thanks to the method according to the invention, the electronic components can be manufactured, finalized and regularly arranged on a strip support. This strip support is in fact used as a temporary support for receiving electronic components and at the same time as an adhesive material, certain areas or portions of which can possibly be transferred, transferred, to each electronic component. Thus, the flexible support can have a double function:

- On the one hand, that of receiving the electronic components, advantageously finalized, on a reel support, for later use during which they will be integrated into a smart card; and

- on the other hand, that of providing an adhesive material which can be used to fix each individual component, in a smart card. In addition, if this adhesive material also has electrical conduction properties in the direction corresponding to its thickness, it can be used to establish an electrical connection between a component and a circuit or antenna located in a card body.

Thus, the electronic components can be transferred directly from the strip support into a cavity in the body of the card.

In this document, the expression "adhesive material" denotes both a material having adhesive properties at room temperature, such as in particular a material called "tacky adhesive", as a material made adhesive by heating, such as '' a hot-melt material. The conditions of use will be adapted to its properties.

The strip support may include in its width several electronic components. Thus, the method according to the invention makes it possible to produce rolls supporting electronic components in large numbers, the electronic components placed on these rollers being finalized and ready to be integrated into cards. The strip supports used for the manufacture of electronic components, for example for the manufacture of modules meeting the ISO 7810 standard, comprise drive holes on each of the longitudinal edges of the strip. Therefore, these strip supports have two rows of drive holes, but may include a variable number of rows of components. Thus, the more rows of components there are in the width of the strip supports (between the two rows of drive holes), the more the useful surface of these supports can be optimized. The density of electronic components per unit area of a strip support can be increased and correspondingly the manufacturing costs per electronic component are reduced. Alternatively, the electronic components can be produced on flexible strips of greater or lesser width in order to optimize the number of electronic components produced per unit of area, then the electronic components are transferred to a strip support of smaller width and comprising a adhesive material, for example for reasons of compatibility with existing materials.

The method according to the invention allows economies of scale by promoting mass production of electronic components.

The method according to the invention further comprises one of the following characteristics, considered in isolation and independently of one another, or in combination with one or more others:

- At least one bonding pad is produced, on a bonding zone of each electronic component supplied, from the adhesive material;

- We realize on an unwound part of the flexible support, a multiplicity of openings in a regular arrangement;

- at least one electronic component is provided having an upper face and a lower face, and at least two distinct thicknesses measured between the upper face and the lower face, at least one bonding zone being located on the lower face at the level of the first of these thicknesses, and at least one zone in excess thickness being situated on the lower face at the level of the second of these thicknesses, this second thickness being greater than the first thickness; - We place each electronic component supplied at an opening, by placing the area in excess in an opening;

- at least one electronic component is transferred, with a portion of adhesive material on their underside, on the flexible support;

- the flexible support is covered with a layer of sticky material on a main face receiving at least one electronic component;

- The adhesive material is arranged on a base strip to form the flexible support, before the bonding area of the electronic component is placed on it, directly in contact with the adhesive material;

- The flexible support comprises a base strip, this base strip being cut so as to leave exposed at least one area of adhesive material, under an electronic component, then the adhesive material is cut at this area so detaching the electronic component with a portion of adhesive material located on a bonding area before transferring it to a smart card;

- the adhesive material is laminated on a base strip, before openings are made through the flexible support formed by the base strip and the adhesive material;

- the adhesive material is a hot melt film;

- The adhesive material is an anisotropic conductive film, electrically conductive depending on its thickness;

- The flexible support comprises paper.

According to another aspect, the invention relates to a method of manufacturing a smart card module in which a flexible support is manufactured in a roll supporting electronic components in accordance with the method described above, each electronic component supported by this flexible support and provided with a portion of adhesive material on a bonding zone, essentially constituting a smart card module.

According to yet another aspect, the invention relates to a method of manufacturing a smart card in which a flexible support is manufactured in a roll supporting electronic components in accordance with the method described above, and at least some are taken electronic components supported by the flexible support to place them in a cavity provided in a smart card. In addition, according to this method of manufacturing a smart card, it is possible to connect each electronic component placed in a smart card to a flexible printed circuit integrated in this smart card.

According to yet another aspect, the invention relates to a flexible roll support supporting electronic components, comprising:

- A multiplicity of cut openings, in a regular arrangement, in the thickness of the flexible support and

- Electronic components having an upper face and a lower face, and at least two distinct thicknesses measured between the upper face and the lower face, at least one bonding zone being located on the lower face at the level of the first of these thicknesses, and a zone in excess thickness being situated on the lower face at the level of the second of these thicknesses, this second thickness being greater than the first thickness, these electronic components being placed, each respectively, at the level of an opening, in placing the area in excess thickness in an opening, each electronic component being placed on the flexible support with an adhesive material placed on a bonding area.

The roll support according to the invention further comprises one of the following characteristics, considered in isolation and independently of one another, or in combination with one or more others:

- the adhesive material is a hot melt film;

- The adhesive material is an anisotropic conductive film, electrically conductive depending on its thickness.

According to yet another aspect, the invention relates to a smart card module manufactured with a method for manufacturing a smart card module as set out above, comprising a portion of adhesive material on a bonding zone. (17).

According to yet another aspect, the invention relates to a smart card comprising at least one cavity in which a module as mentioned above is fixed thanks to the portion of adhesive material present on a bonding zone.

Other features and advantages of the invention will appear on reading the detailed description, accompanied by figures of several examples of mode of implementation of the invention.

In the drawings: [Fig.1] schematically represents different stages of a first example of implementation of the method according to the invention;

[Fig. 2] schematically represents different stages of a second example of implementation of the method according to the invention;

[Fig. 3] schematically represents different stages of a third example of implementation of the method according to the invention;

[Fig. 4] schematically represents different stages of a fourth example of implementation of the method according to the invention.

The invention is exemplified below with the aid of several examples of implementation of the process for manufacturing a roll support for electronic components.

According to a first example of implementation of the method according to the invention, it comprises the following steps (Fig. 1):

The supply and unwinding of a portion of a roll of complex material forming a flexible support 10 comprising a flexible base strip 11 with two main faces, one of these main faces being at least partially covered with an adhesive film 12; alternatively, according to a variant, the base band

1 1 is supplied in a roll, then unrolled and laminated with an adhesive film 12, to form a flexible support 10 which is directly used in the next perforation step;

The perforation A of the flexible support 10 from the previous step so as to create openings 13 through both the base strip 11 and areas of adhesive film 12;

Cutting B by flush (kiss cutting) the adhesive film

12 and delamination thereof to leave at least one area of adhesive film 12 in the vicinity of each opening 13;

The placement C of electronic components 14, each respectively at an opening 13 produced in the perforation step A, and resting on the areas of adhesive film 12 left on the base strip 1 1 during cutting B and associated delamination;

The base strip 1 1 is for example a paper-based veil ("paper liner" in English) 90 to 100 micrometers thick and 35 mm wide to be compatible with the format of industrial equipment of card manufacturing chip. It is for example glassine (also called crystal paper, polyester (PET, PEN) or polyimide.

The adhesive film 12 is for example an anisotropic conductive film, providing electrical conduction according to its thickness. It has for example a thickness of between 40 to 50 μm and covers, for example completely, the paper.

The flexible support 10 with the adhesive film 12 is for example a product having the reference HAF® 8414 from the company Tesa® or EH8030-50 from the company Dexerials.

Cut-out B by flushing can be carried out using a laser or a rotary punching machine.

The electronic components 14 are arranged on the flexible support 10, for example, by transfer arm (pick & place) from a tray. The electronic components 14 are fixed to the flexible support 10, for example by applying a pressure of 2 bars, at a temperature of 130 ° C., for 1 second.

The electronic components 14 can be modules of the ISO 7810 type or functional modules (“feature modules” in English) of the biometric control device type, visual cryptogram displays, etc.

The electronic components 14 essentially have an upper face 15 and a lower face 16, and at least two distinct thicknesses E and E ’measured between the upper face 15 and the lower face16. At least one bonding zone 17 is located on the lower face 16 at the level of the first E of these thicknesses. An extra thickness zone 18 is located on the lower face 16 at the level of the second E ′ of these thicknesses. The second thickness E ’is greater than the first thickness E.

The fact that the electronic components 14 have a thickened area 18 may come, for example, from the fact that an electronic chip and its electrical connections are encapsulated in a protective dome of resin ("glob-top" in English) . In all cases, the presence of openings 13 makes it possible to better position and accommodate the electronic components 14 when the base strip 1 1 is in the form of a roll, the thickness of the base strip 1 1 then making it possible to compensate at least partly the thickness E 'of the electronic components 14.

Following this preparation and implementation of the electronic components 14 on a roll support for electronic components formed from the flexible support 10, the electronic components 14 can be removed (for example by arm of transfer - step D) of the flexible support 11, with their adhesive film 12 disposed at the level of the bonding pads 17, to be integrated, in known manner, into a cavity formed in a card body.

The electronic components 14, such as ISO 7810 modules, can be produced on the very wide strips (for example 70 or 150 millimeters wide) for greater densification of the production of the electronic components 14. Optionally, for reasons of compatibility with existing equipment and tools, the electronic components 14 are transferred to flexible supports 10 of smaller width (for example 35 millimeters wide) before being integrated into card bodies.

According to a second example of implementation of the method according to the invention, it comprises the following steps (Fig. 2):

The supply and unwinding of a portion of a roll of a complex material forming a flexible support 10 and comprising a flexible base strip 11 with two main faces, one of these main faces being at least partly covered an adhesive film 12; alternatively, according to a variant, the base strip 1 1 is supplied in a roll, then unrolled and laminated with an adhesive film 12, to form a flexible support 10 which is directly or not used in the next perforation step;

Cutting B by flush ("kiss cutting" in English) of the base strip 1 1 and delamination thereof in the vicinity of each opening 13, to leave at least one area of adhesive film 12 without base strip 1 1 underlying, in the vicinity of each opening 13;

The placement C of electronic components 14, each respectively at an opening 13 produced in the perforation step A, and resting on the areas of adhesive film 12 not themselves resting on the base strip 1 1 ;

Cutting D of the adhesive film in order to essentially preserve areas of adhesive film 12 under the bonding zones 17 of the electronic components 14. This cutting D can be carried out practically concomitantly or just before a step E consisting in removing (for example by arm components) electronics 14, with their adhesive film 12 arranged at the bonding pads 17, to integrate them, in known manner, into a cavity formed in a card body.

These steps can essentially be implemented with products and conditions essentially identical or similar to those described in relation to the first mode of implementation.

According to a third example of implementation of the method according to the invention, it comprises the following steps (Fig. 3):

The unwinding of a flexible support 20 comprising a base strip 21, flexible in a roll with two main faces, one of these main faces being at least partially covered with a layer of sticky material 22 ("tacky adhesive" in English); alternatively, according to a variant, the base strip 1 1 is supplied in a roll, then unrolled and covered with a layer of sticky material 22, to form the flexible support 20 which is directly or not used in the following step of perforation;

The perforation has flexible support 20 from the previous step, so as to create openings 25 through both the base strip 21 and the layer of sticky material 22;

Preparation b of the electronic components 14 with a hot-melt material 23, optionally anisotropic conductor on bonding zones 17 of the components 14, with a protective film 24 protecting the hot-melt material on the face which is not in contact with the electronic component 14. For example, this preparation is carried out continuously by laminating the hot-melt material 23 in a strip, on a strip of flexible material comprising components 14, as may be the case in particular if the electronic components 14 are continuously manufactured on these same strips of flexible material.

The introduction g of electronic components 14, each respectively at an opening 25 produced in the perforation step a, and by resting the pads of hot-melt material 23 on the layer of sticky material 22, the protective film 24 having been previously peeled, their thickened area 18 being placed in an opening 25.

Following this preparation and implementation of electronic components 14 on a roll support for electronic components formed of the flexible support 20, the electronic components 14 can be removed (for example by transfer arm - step d) from the flexible support 20, with their adhesive film 23 disposed at the bonding pads 17, to be integrated, in a known manner, into a cavity housed in a card body.

The flexible support 20 comprising the base strip 21 with its layer of sticky material 22 is for example a polymer substrate with an adhesive layer having a controlled tack. The flexible support 20 corresponds for example to a product having the reference PET8030F from the company Dexerials (or a similar product).

The electronic components 14 are arranged, in step y, on the flexible support 20, by transfer arm for example. The electronic components 14 are positioned (and thus attached) on the flexible support 20 at room temperature.

As for the examples of previous embodiments, the electronic components 14 can be modules of the ISO 7810 type or functional modules (“feature modules” in English) of the biometric control device type, visual cryptogram displays. , etc.

According to a fourth example of implementation of the method according to the invention, it comprises the following steps (Fig. 4):

- The supply of a flexible strip 31 of dielectric material, for example 150 mm wide; the material constituting this flexible strip is for example glass-epoxy;

- The coating of one of the main faces of the flexible strip 31 with an adhesive;

- The perforation of the flexible strip 31 coated with the adhesive;

- The lamination of a sheet of electrically conductive material (for example copper, aluminum, etc.) on the face of the flexible strip 31 coated with the adhesive; alternatively these four stages (supply of the flexible strip, coating of the adhesive, perforation, lamination of the sheet of conductive material) are replaced by a stage of supply of a strip of laminate ("clad" in English) formed of a sheet of electrically conductive material supported by a strip of dielectric material;

- The realization R of a number of steps (perforations, the possible lamination of a copper foil on another face, photo-lithography of patterns for forming contacts on a first face and possibly other patterns on a second face, fixing an electronic chip on the second face, connecting the electronic chip 32 to the contacts, encapsulating the electronic chip 32 and its connections in a resin dome 33) corresponding to the continuous manufacture (from roll to roll) of electronic components 14 (in the present example of ISO modules);

- The cutting of the electronic components 14 (maintained for example by suction on a support arm) and their transfer (by the support arm) on a flexible adhesive support 10 (for example a support comprising a hot-melt material or consisting of a hot-melt material), for example; this flexible support has for example a width of 35mm for reasons of compatibility with machines and tools for inserting modules into a smart card; if a connection is necessary between the electronic components 14 and elements (antenna, flexible printed circuit, etc.) present in the card body 100, the flexible adhesive support 10 is also conductive according to at least its thickness; openings 13 have been made (for example by cutting by flush, in a manner similar to step b described above) prior to the transfer of the electronic components 14 into the flexible support 10 adhesive, and optionally conductive, to keep at least one adhesive pad under each electronic component 14; and

- The transfer of the module into a cavity 101 milled in the body of a smart card 100.

Claims

claims

[Claim 1] Method of manufacturing a roll holder for electronic components, in which

- we provide a flexible support (10, 20) in roll that we unroll,

- at least one electronic component (14) is provided having an upper face (15) and a lower face (16), and at least two distinct thicknesses (E, E ') measured between the upper face (15) and the lower face (16), at least one bonding zone (17) being situated on the lower face (16) at the level of the first (E) of these thicknesses, and at least one zone in excess thickness (18) being situated on the lower face (16) at the second (E ') of these thicknesses, this second thickness (E') being greater than the first thickness (E),

characterized by the fact that

the flexible support (10, 20) comprises an adhesive material (12, 22) adapted to receive and fix the electronic component (14) before transferring this electronic component (14) to a smart card (100),

- a multiplicity of openings (13, 25) are made on an unwound part of the flexible support (10, 20) according to a regular arrangement,

- each electronic component (14) supplied is placed on an unwound part of the flexible support (10, 20), at an opening (13, 25), by placing the area in excess thickness (18) in one of the openings (13, 25) and

- At least one bonding pad is produced, on a bonding zone (17) of each electronic component (14) supplied.

[Claim 2] A method according to claim 1, wherein the bonding pad (17) is made from the adhesive material (12).

[Claim 3] Method according to one of the preceding claims, in which at least one electronic component (14) is transferred, with a portion of adhesive material (23) on its underside (16), onto the flexible support (20) .

[Claim 4] Method according to claim 3, in which the flexible support (20) is covered with a layer of adhesive material (22) on a main face receiving at least one electronic component (14).

[Claim 5] Method according to one of claims 1 to 3, wherein the adhesive material (12) is arranged on a base strip (1 1) to form the flexible support (10), before the bonding area ( 17) of the electronic component (14) is placed on it, directly in contact with the adhesive material (12).

[Claim 6] Method according to one of the preceding claims, wherein the flexible support (10) comprises a base band (1 1), this base band (1 1) being cut so as to leave exposed at least one area adhesive material (12), under an electronic component (14), then the adhesive material (12) is cut at this area so as to detach the electronic component (14) with a portion of adhesive material (12) located on a bonding area (17) before transferring it to a smart card (100).

[Claim 7] Method according to one of the preceding claims, wherein the adhesive material (12, 22) is laminated on a base strip (1 1), before openings (13, 25) are made through the flexible support (10) formed by the base strip (1 1) and the adhesive material (12, 22).

[Claim 8] Method according to one of the preceding claims, in which the adhesive material (12) is a hot-melt film.

[Claim 9] Method according to one of the preceding claims, in which the adhesive material (12) is an anisotropic conductive film, electrically conductive according to its thickness.

[Claim 10] Method according to one of the preceding claims, in which the flexible support comprises paper.

[Claim 1 1] Method for manufacturing a smart card module in which a flexible support (10, 20) is produced in a roll supporting electronic components (according to a process according to one of claims 1 to 10) 14), each electronic component (14), supported by this flexible support (10, 20) and provided with a portion of adhesive material (12, 23) on a bonding area (17), essentially constituting a smart card module.

[Claim 12] Method for manufacturing a smart card in which a flexible support (10) is manufactured in a roll supporting electronic components (14) according to a process according to one of claims 1 to 10, samples are taken at least some of the electronic components (14) supported by the flexible support (10) to place them in a cavity (101) formed in a smart card (100).

[Claim 13] The method of claim 12, wherein each electronic component (13) disposed in a smart card (100) is connected to a flexible printed circuit integrated in this smart card (100).

[Claim 14] Flexible roll support supporting electronic components (14), comprising:

- a multiplicity of openings (13, 25) cut, according to a regular arrangement, in the thickness of the flexible support (10) and

- electronic components (14) having an upper face (15) and a lower face (16), and at least two distinct thicknesses (E, E ') measured between the upper face (15) and the lower face (16), at least one bonding zone (17) being situated on the lower face (16) at the level of the first (E) of these thicknesses (E, E '), and an extra thickness zone (18) being situated on the lower face (16) at the second (E ') of these thicknesses (E, E'), this second thickness (E ') being greater than the first thickness (E), these electronic components (14) being placed, each respectively , at an opening (13, 25), by placing the area in excess thickness (18) in an opening (13, 25), each electronic component (14) being arranged on the flexible support (10, 20) with a adhesive material (12, 23) disposed on a bonding area (17).

[Claim 15] Support according to claim 14, in which the adhesive material (12, 23) is a hot-melt film.

[Claim 16] Support according to claim 14 or 15, wherein the adhesive material (12, 23) is an anisotropic conductive film, electrically conductive according to its thickness.

[Claim 17] Chip card module manufactured with a method according to claim 11, comprising a portion of adhesive material (12, 23) on a bonding area (17).

[Claim 18] Chip card comprising at least one cavity in which a module according to claim 17 is fixed thanks to the portion of adhesive material (12, 23) present on a bonding zone (17).