FR2786009A1 - METHOD FOR MANUFACTURING A HYBRID CHIP CARD BY DOUBLE-SIDED PRINTING - Google Patents

Abstract

The invention concerns a method for making hybrid smart cards capable of operating with or without contact. The method is characterised in that it consists in producing a connecting terminal strip (110) by an operation which consists in printing a conductive substance on a first surface (510) of an insulating foil (500); then in producing first interconnecting pads (115, 116) and an antenna (120), at the ends of which are provided second interconnection pads (125, 126), by another printing operation using the same conductive substance on a second surface (520) of the insulating foil (500). The first interconnection pads (115, 116) are electrically connected to the connecting terminal strip (110) via through holes (530) previously produced in the insulating foil (500) thickness and filled with said conductive substance during the printing operations.

Description

METHOD FOR MANUFACTURING A HYBRID CHIP CARD BY
DOUBLE SIDED PRINTING
The present invention relates to the manufacture of smart cards comprising an integrated circuit chip, the contact pads of which are connected to interface elements constituted by a connection terminal block and an antenna. This type of card is capable of ensuring both contact and contactless operation. We will call this type of card, in the rest of the description, hybrid card or combicard.

 With hybrid cards, the exchange of information with the outside is done either by the antenna, which ensures an electromagnetic coupling (in principle of inductive type) between the electronics of the card and a reader (it is the operation without touching) ; or by the terminal block contacts flush with the surface of the card, which ensure an electrical transmission of data when they are in contact with a read head of a reader (this is contact operation).

 Such cards are intended for various operations such as, for example, banking operations, telephone communications, various identification operations, debit operations and recharging of unit of account, and all kinds of operations that can s '' Perform either by inserting the card in the slot of a reader, or remotely by electromagnetic coupling between a transceiver terminal and the card placed in an action area of this terminal.

 Hybrid cards must necessarily have standardized dimensions identical to those of conventional smart cards only provided with contacts. The dimensions of these cards are defined by the usual standard ISO 7810 which corresponds to a standard format card 85mm long, 54mm wide and 0.76mm thick.

 These standards impose severe constraints for manufacturing. The very small thickness of the card is in particular a major constraint since it is necessary to provide for the incorporation of an antenna in the card.

 In addition, other technical problems arise, such as problems in positioning the antenna relative to the card (since the antenna occupies almost the entire surface of the card), problems in positioning the integrated circuit module. (including the integrated circuit chip and its contacts) which ensures the electronic operation of the card, and problems of precision and reliability of the connection between the module and the antenna. The constraints of mechanical strength, reliability and manufacturing cost must also be taken into account.

 Solutions have already been envisaged in the prior art for making combicards. A first method, which is illustrated in FIG. 1, consists in installing, in a cavity 11 hollowed out in a card body 10, a module M consisting of a double-sided printed circuit which is electrically connected to an antenna 15 by via connection wells 13. Connection wells 13 are formed in the cavity 10, so as to make accessible the connection terminals 12 of the antenna 15 which is embedded in the card body. The electrical connection, between the contact pads 22 of the module M and the antenna, is ensured by means of conductive elements 14 which are provided in the connection wells 13. The module M, meanwhile, has ranges of contact 21, on its upper face, intended to form the access contacts of the smart card, and contact pads 22, on its lower face, intended to be connected to the antenna. These contact pads 21 and 22 are made of nickel-plated gold copper, on an insulating sheet 20. Conductive wires 27 connect an integrated circuit chip 25 to the contact pads 21, forming the connection terminal block of the card, passing through vias 23 hollowed out in the thickness of the insulating sheet. Other conductive wires 27 connect the chip 25 to the other contact pads 22. An encapsulation resin 28 protects the chip 25 and the wires 27.

 This manufacturing process however has several drawbacks. The components (copper, nickel and gold) of the contact pads of the module are in particular very expensive. In addition, this method requires not only the machining of a cavity but also special machining to produce the connection wells intended to update the connection terminals of the antenna. This specific machining of the wells above the antenna connection terminals is not always easy to master. In addition, the insertion of a double-sided module, as well as the filling of the connection wells with a conductive element, are delicate operations to implement, which contribute to reducing the production yield and, consequently, to increasing the cost price of the cards. Finally, the adhesion between the golden contact pads of the module and the conductive element filling the connection wells is not always of good quality. This poor adhesion leads to low reliability of the electrical connection between the module and the antenna, which implies that the number of cards intended for scrap remains still high.

 A second solution proposed in the prior art, and illustrated in FIG. 2, consists in not using a micromodule intended to be inserted.

This solution avoids the specific machining of the connection wells as well as their filling with a conductive element to establish a connection between the module and the antenna.

 This solution consists more particularly in digging a cavity 55 in a card body 50 having at heart an antenna wire 60, produced by inlaying, laminating or printing a substance and at the ends of which are provided connection terminals 61,62 . An integrated circuit chip 70 is then fixed in the bottom of the cavity, by gluing for example, with its active face and its contact pads 71 oriented towards the opening of the cavity. A connection terminal block 65 is then produced so that its contact pads are flush with the surface of the card and are extended in the cavity by conductive tracks 66 intended to be connected to the output pads 71 of the chip 70. This terminal block thus that the connections with the chip are made by depositing, by means of a syringe or the like, a conductive resin 63 of low viscosity which remains flexible after its application. The output pads 71 of the chip 70 are connected in the same way to the connection terminals 61, 62 of the antenna G0. Finally, the chip and the interconnections are encapsulated in a protective resin which is injected into the cavity 55.

 However, this solution requires the carrying out of a large number of operations which contributes to increasing the cost of manufacturing the cards. The machining of a cavity to place the chip there is also always necessary. In addition, the technique of dispensing low viscosity resin does not make it possible to obtain satisfactory manufacturing yields: they are too low and therefore contribute to raising the cost price of hybrid cards.

 The present invention overcomes the drawbacks posed by the prior art and improves the methods of manufacturing hybrid cards by reducing the number of steps and improving the production yield. The invention also makes it possible to manufacture such combicards without necessarily machining a cavity in the card body.

 For this, the invention more particularly provides a method of manufacturing a chip card comprising at least one integrated circuit chip, the output pads of which are electrically connected respectively to a connection terminal block, by means of first pads interconnection, and to an antenna, via second interconnection pads. This method is characterized in that said connection terminal block is produced by an operation of printing an electrically conductive substance on a first face of an insulating sheet; said antenna and said first and second interconnection pads are produced by another printing operation of said electrically conductive substance on a second face of said insulating sheet; and in that the said first interconnection pads are electrically connected to the said connection terminal block by means of vias previously hollowed out in the thickness of the said insulating sheet and filled with the said electrically conductive substance during the printing operations.

 The vias are made by punching, by laser cutting or by water jet cutting of the insulating sheet.

 According to another characteristic of the invention, during the first printing operation, a vacuum is created on the insulating sheet to facilitate the filling of the vias with the electrically conductive substance.

 According to another characteristic of the invention, the electrically conductive substance used is an ink based on polymeric resin loaded with conductive particles or an ink based on intrinsically conductive polymeric resin.

 The insulating sheet used, for its part, is a plastic sheet of polyvinyl chloride (PVC), acrylonitrile butadiene styrene (ABS), polystyrene (PS), polyethylene terephthalate (PET), polyethylene (PE), polycarbonate (PC) type. ), polypropylene (PP), or a sheet of paper or a sheet based on cellulose derivative.

 According to another characteristic of the invention, the antenna is produced in such a way that it has dimensions close to the surface of a smart card.

 According to yet another characteristic of the invention, the insulating sheet has a thickness of between 0.2 and 0.4 mm and at least one other sheet of plastic material is applied to its underside by colamination.

 According to yet another characteristic of the invention, the insulating sheet has a thickness of between 0.2 and 0.4 mm and another sheet of plastic material is applied to its underside by overmolding.

 According to yet another characteristic of the invention, the insulating sheet has a thickness identical to or close to that of a conventional smart card, the integrated circuit chip is housed in a cavity formed in the thickness of said sheet, and a insulating varnish is applied to the underside of said sheet in order to protect the chip, the antenna and the interconnection pads.

 According to another characteristic of the invention, the antenna is produced on a reduced surface so that the insulating sheet, provided with the connection terminal block, the antenna, the interconnection pads and the chip, forms a micromodule with incorporated antenna intended to be placed in a cavity of a card body.

 The number of operations making it possible to produce a hybrid card by the method according to the invention is considerably reduced. The connection terminal block, the antenna and the interconnection pads are produced on a sheet which can be cut in chip card format, at any time during the process. It is therefore no longer necessary to dig a cavity in a card body. Thanks to the manufacturing method according to the invention, the production rate is considerably increased and, consequently, the cost price of the hybrid cards is considerably reduced.

 Another object relates to a smart card operating with and / or without contact, characterized in that it is obtained by the method according to the invention.

Other features and advantages of the invention will appear on reading the description given by way of illustrative but non-limiting example and made with reference to the appended figures which schematize:
FIG. 1, already described, a combicard during a manufacturing process of the prior art,
FIG. 2, already described, a combicard obtained from another known manufacturing process,
FIG. 3, a top view of an insulating plate carrying several cards according to the invention during manufacture,
FIG. 4, a bottom view of the plate of FIG. 3,
FIG. 5, a sectional view of an insulating sheet, cut out in card format, during the manufacturing steps of the method according to the invention,
FIG. 6A, a bottom view of a smart card according to the invention during its manufacture,
FIG. 6B, a sectional view along AA of the card in FIG. 6A,
FIG. 6C, a sectional view along AA of the card of FIG. 6A according to an alternative embodiment,
FIG. 7, a sectional view of a combo card during manufacture according to an alternative embodiment of the method according to the invention,
FIG. 8, a double-sided module with incorporated antenna produced according to the present invention and ready to be inserted in a card body.

 The manufacturing process of smart cards. hybrids according to the invention consists in producing the interface elements of the card, essentially consisting of a connection terminal block and an antenna, by printing an electrically conductive substance on both sides of an insulating sheet 500. The insulating sheet 500, as shown in FIGS. 3 and 4 respectively seen from above (upper face 510) and seen from below (lower face 520), can be in the form of a plate whose surface is much greater than that of a smart card. In this case, the interface elements of several cards are produced on the plate and a cut in card format is carried out subsequently.

 The insulating sheet 500 can, in an alternative embodiment, be cut beforehand in card format. In this case, the interface elements of each card are produced on insulating sheets which pass one after the other.

 The insulating sheet is a plastic sheet, for example of polyvinyl chloride (PVC), acrylonitrile butadiene styrene (ABS), polystyrene (PS), polyethylene terephthalate (PET), polyethylene (PE), polycarbonate (PC) or else polypropylene (PP). The insulating sheet can also be a sheet of paper or even a sheet made from a cellulose derivative.

 In FIG. 3, connection terminals 110, 210, 310 of several cards 100, 200, 300 are shown diagrammatically. These connection terminals are made to dimensions complying with the ISO standard and include contact pads intended for establishing electrical contact with the connectors of a read head of a reader.

 In FIG. 4, the antennas 120,220,320 of these cards 100,200,300 are shown diagrammatically, as well as interconnection pads 115,116 and 125,126 of an interconnection circuit. The first interconnection pads referenced 115,116 are electrically connected to the connection terminal block 110 located on the other face. They are intended to connect an integrated circuit chip to the connection terminal block.

Only two of these first interconnection pads are shown in FIG. 4, but of course their number can be greater. There are in fact, in general, as many of these first interconnection pads as there are contact pads in the connection terminal block.

 Other second interconnection pads 125, 126 are provided at the ends of the antenna to allow the integrated circuit chip to be connected to the antenna.

 FIG. 5 represents a sectional view of an insulating sheet 500 cut in the format of a card 100. Prior to the production of the interface elements and the interconnection circuit, vias 530 are formed in the thickness of the insulating sheet 500. These vias 530 are intended to allow a connection between the two faces of the insulating sheet, and more particularly to connect the connection terminal block 110 to interconnection pads 115, 116. The realization of these vias 530 is carried out by punching the insulating sheet, or by laser cutting, or by water jet cutting of this insulating sheet. These vias 530 are produced at a controlled location with respect to a determined position of the connection terminal block 110.

 After having dug these vias 530, said terminal block 110, the antenna 120 and the interconnection circuit are produced. For this, a first printing operation is carried out on one of the faces of the insulating sheet 500. It does not matter the face and the interface element printed during this first operation.

In the example, it is for example the connection terminal 110 which is printed first on the upper face 510 of the insulating sheet.

 The printing of the electrically conductive substance can be done in various known ways. Thus, it can for example be carried out according to a screen printing technology, or offset printing, or pad printing, or flexography printing or the like. During this first printing operation, care must be taken to cover each via 530 with the electrically conductive substance. Thus, the vias 530 are partly filled with this conductive substance during the first printing operation.

 In an alternative embodiment of the method according to the invention, it is possible, for example, to apply a vacuum to the insulating sheet in order to facilitate the filling of the vias 530 with the conductive substance.

This vacuum can be achieved by applying mechanical pressure to one side of the insulating sheet opposite to that which is printed, in order to deform and enlarge the opening of the vias opening onto the side to be printed. It can also be created by a vacuum produced opposite the face to be printed in order to entrain the conductive substance in the vias.

 A second printing operation is then performed to print the other interface elements on the other side. In this example, the antenna 120 and the various interconnection areas 115, 116; 125, 126 are therefore printed on the underside 520 of the insulating sheet. This printing operation initially consists in printing the antenna turns 120 and its interconnection pads 125,126, as well as the interconnection pads 115,116 associated with the connection terminal block 110. During this operation printing, the vias 530 are completely filled with the conductive substance so that the electrical connection between the two faces 510, 520 of the insulating sheet 500 is established. The interconnection pads 115, 116 associated with the terminal block 110 then cover the through vias.

 The interconnection pads 125,126 being provided inside the antenna turns, an insulating bridge must be made, in a second step, between the end of the outer turn and one of the interconnection pads 126 of the 'antenna. This insulating bridge consists in applying an insulating protective film 121, such as a varnish, to the antenna turns intended to be crossed, in order to avoid a short circuit.

Printing is then completed by connecting the end of the external turn to the interconnection pad 126. For this, the conductive substance is applied to the insulating varnish 121.

 The electrically conductive substance used is an ink based on polymer resin charged with conductive particles, such as for example an epoxy resin charged with particles of silver, or copper or gold. It can also be an intrinsically conductive polymer resin, such as polypirhole for example. In all cases, the polymer resin comprises a thermosetting polymer or a thermoplastic polymer, or else a mixture of the two. It can also optionally include a solvent to reduce its viscosity and facilitate its use.

 An integrated circuit chip 130 is then transferred to the underside 520 of the insulating sheet 500 and connected respectively to the first interconnection pads 115,116 associated with the connection terminal block 110, and to the second interconnection pads 125,126 associated with the antenna 120 The integrated circuit chip 130 can be transferred in various conventional and well known ways.

 A first method consists in sticking the chip 130 to the insulating sheet 500 and making the electrical connections via conductive wires 135, between the output pads 131 of the chip and the various interconnection pads, according to the technique well known as "wire bonding" in Anglo-Saxon literature. The chip 130 and the connection wires 135 are then encapsulated in a protective resin 140. In this case, the ink will have to present, with the known processes of "wedge bonding" or "wire bonding", a quite particular formulation conferring on it, after drying, a property of weldability.

 The integrated circuit chip 130 can also be transferred according to a well-known arrangement known as a "flip chip" in English literature, according to which the output pads of the chip are directly transferred to the different interconnection pads and they are fixed to the using an electrically conductive adhesive. This arrangement is illustrated in the bottom view of FIG. 6A and in the sectional view along A-A of FIG. 6B.

 Another possibility for transferring the chip 130, illustrated in the sectional view of FIG. 6C, consists in gluing the chip 130 on the underside of the insulating sheet 500, then in making the electrical connection, between the output pads 131 of the chip 130 and the various interconnection areas, by deposition, by means of a syringe or the like, of a conductive resin 145 with low viscosity.

 In the last two cases which have just been described, it is not essential to encapsulate the chip in a protective resin.

 Preferably, the antenna is given dimensions close to those of the card, in order to maximize the range of the antenna. The antenna is therefore produced over a length close to 85 mm and over a width close to 54 mm (see FIGS. 4 and 6A).

 The hybrid smart card according to the invention is then finalized. For this, a first method consists in carrying out a hot colamination. In this case, the insulating sheet 500 is associated with other thermoplastic sheets (a single additional sheet referenced 600 is shown in Figures 6B and 6C; and two additional sheets 600 and 650 are shown in Figure 5). These additional sheets are applied to the underside 520 of the insulating sheet 500 in order to drown the antenna and the electrical connections. They are optionally perforated opposite the integrated circuit chip (like sheet 650 in FIG. 5) and a resin can optionally be deposited in the space remaining between the chip and this perforation.

All of the sheets are then hot pressed.

 When the insulating sheet 500 has not been previously cut, a plate is thus obtained comprising several hybrid cards which are then cut in card format. When the insulating sheet has been previously cut into card format, a hybrid smart card is obtained.

 The smart card can also be finalized by assembling sheets by cold colamination.

 Another method to finalize the card is to perform overmolding. In this case, the insulating sheet is placed in a mold so that the connection terminal block is applied against one of the walls of the mold. A thermoplastic resin is then injected or poured in order to flood the antenna and the interconnection pads in a layer. One then obtains either a plate intended to be cut in card format, or a combicard with standardized dimensions, or finer, when the insulating sheet has been cut beforehand.

 In the cases which have just been described, the insulating sheet 500 has a thickness of, for example, between 0.2 and 0.4 mm.

 According to another alternative embodiment, the insulating sheet 500 may have a thickness identical to or close to that of a conventional smart card, that is to say a thickness of the order of 0.8 mm. This variant is shown diagrammatically in the sectional view of FIG. 7. In this case, it is possible, for example, to provide a cavity 540 in the insulating sheet 500 to accommodate the integrated circuit chip 130 therein. This chip will be connected respectively to the first pads of interconnection 115,116 associated with the terminal block 110 and the second interconnection pads 125,126 associated with the antenna 120 either by wire wiring, or by means of a conductive resin dispensed using a syringe or the like. In this case, the thickness of the insulating sheet being identical or close to that of a smart card, an insulating varnish 700, of very small thickness, is applied to the underside 520 supporting the chip, the antenna and interconnections, in order to protect them against external aggressions.

The manufacturing method according to the invention has the advantage of comprising only steps which can be controlled using a
Computer Aided Vision. It makes it possible to manufacture portable devices such as combicards capable of operating with and without contact, but also other devices which may include more than one antenna. It also has the advantage of making it possible to produce a fine card, of the combicard type, of thickness less than the ISO standard, in particular of the order of 40 ohm. The card decoration operations can be carried out at different times during the manufacturing process, either on the insulating sheet before the chip is transferred, or on the plate before cutting in card format, or on the finished card.

 In an alternative embodiment of the method according to the invention, illustrated in FIG. 8, the antenna 120 can be made to reduced dimensions, for example to dimensions of 10 or 20 mm by 10 mm.

This reduced surface makes it possible to manipulate the insulating sheet 500 provided with the connection terminal block 110, the antenna 120, the interconnection circuit and the integrated circuit chip 130 like a micromodule 800 with incorporated antenna well known in the world of Smartcard. This case can be envisaged when the integrated circuit chip has a low consumption or when the application in the contactless mode does not require a large range (for example when the distance between the card and a reader is less than 1 cm).

 One can then use the traditional insertion methods to transfer the micromodule 800 thus formed into a cavity 910 of a card body 900.

The advantage in this case lies in the fact that the micromodule is produced quickly (due to the reduced number of operations), which makes it possible to improve productivity.

 The method according to the invention therefore has the advantage of being inexpensive and quick to implement since it comprises a reduced number of steps and uses inexpensive materials (insulating sheet and conductive ink). It therefore makes it possible to increase the production yield and to decrease the manufacturing cost. In addition, the insulating sheet used generally has any surface, greater than that of a card, and it is cut in card format, or in micromodule format as the case may be, at any time during the process. This process does not necessarily require the opening of a cavity in the card body, or the production of a micromodule.

Finally, the electrical connections between the chip and the various interconnection pads are very reliable, so that the number of cards intended for scrap is considerably reduced.

Claims (16)

 1. Method for manufacturing a smart card comprising at least one integrated circuit chip (130), the output pads (131) of which are electrically connected to a connection terminal block (110), respectively, via first pads interconnection (115,116), and to an antenna (120), via second interconnection pads (125,126), characterized in that said connection terminal block (110) is produced by a printing operation of an electrically conductive substance on a first side (510) of an insulating sheet (500); said antenna (120) and said first (115, 116) and second (125,126) interconnection pads are produced by another printing operation of said electrically conductive substance on a second face (520) of said insulating sheet (500) ; and in that said first interconnection pads (115,116) are electrically connected to said connection terminal block (110) by means of vias (530) previously hollowed out in the thickness of said insulating sheet (500) and filled with said substance electrically conductive during printing operations.  2. Method according to claim 1, characterized in that the vias (530) are produced by punching, or by laser cutting, or by water jet cutting of the insulating sheet (500).  3. Method according to one of claims 1 to 2, characterized in that during the first printing operation, a vacuum is created on the insulating sheet (500) to facilitate the filling of the vias (530) with the substance electrically conductive.  4. Method according to one of claims 1 to 3, characterized in that the printing operations of the electrically conductive substance are carried out by a screen printing technology, or an offset printing technology, or a printing technology by pad printing or flexography.  5. Method according to one of claims 1 to 4, characterized in that the integrated circuit chip (130) is electrically connected to the first (115,116) and the second (125,126) interconnection pads either by bonding its pads outlet (131) on said interconnection pads using a conductive adhesive, either by depositing on its outlet pads (131) and said interconnection pads, by means of a syringe or the like, of a low viscosity conductive resin (145).  6. Method according to one of claims 1 to 4, characterized in that the integrated circuit chip (130) is electrically connected to the first (115,116) and seconds (125,126) interconnection pads via conductive wires ( 135).  7. Method according to any one of the preceding claims, characterized in that the electrically conductive substance used is an ink based on polymeric resin loaded with conductive particles, or an ink based on an intrinsically conductive polymeric resin.  8. Method according to claim 7, characterized in that the polymer resin comprises a thermosetting polymer and / or a thermoplastic polymer.  9. Method according to any one of the preceding claims, characterized in that the insulating sheet (500) used is a plastic sheet of polyvinyl chloride (PVC), acrylonitrile butadiene styrene (ABS) type; polystyrene (PS), polyethylene terephthalate (PET), polyethylene (PE), polycarbonate (PC), or polypropylene (PP), or a sheet of paper or a sheet based on cellulose derivative.  10. Method according to any one of the preceding claims, characterized in that the antenna (120) is produced so that it has dimensions close to the surface of a smart card.  11. Method according to any one of the preceding claims, characterized in that the insulating sheet (500) has a thickness of between 0.2 and 0.4 mm and at least one other sheet of plastic material (600,650) is applied to its lower face (520) by colamination.  12. Method according to one of claims 1 to 10, characterized in that the insulating sheet (500) has a thickness of between 0.2 and 0.4 mm, and another plastic sheet is applied to its underside (520) by overmolding.  13. Method according to one of claims 1 to 10, characterized in that the insulating sheet (500) has a thickness identical to or close to that of conventional smart cards, in that the integrated circuit chip (130) is housed in a cavity (540) formed in the thickness of said sheet (500), and in that an insulating varnish (700) is applied to the underside (520) of said sheet (500) in order to protect the chip ( 130), the antenna (120) and the interconnection pads (115,116; 125,126).  14. Method according to one of claims 1 to 9, characterized in that the antenna (120) is produced on a reduced surface so that the insulating sheet (500), provided with the connection terminal block (110), antenna (120), interconnection pads (115,116; 125,126) and the integrated circuit chip (130), forms a micromodule (800) with incorporated antenna intended to be placed in a cavity (910) of a card body (900).  15. Method according to any one of the preceding claims, characterized in that the insulating sheet (500) has any surface, greater than that of a card, and in that it is cut in card format, or in format micromodule, at any point in the process.  16. Smart card operating with and / or contactless, characterized in that it is obtained by the method according to any one of the preceding claims.