METHOD FOR PRODUCING A SINGLE-SIDED ELECTRONIC MODULE INCLUDING INTERCONNECTION ZONES

Abstract

The invention relates to a method for producing a module having an electronic chip including metallisations which are accessible from a first side of the metallisations and an integrated circuit chip which is arranged on the second side of the metallisations, opposite the first side. The method comprises the step of forming electrical interconnection elements which are separate from the metallisations, directly connecting the chip, and are arranged on the second side of the metallisations. The invention also relates to a module corresponding to the method and to a device comprising said module.

Claims

1-11. (canceled)

12. A method for manufacturing a module having an electronic chip, comprising: metallisations accessible from a first side of the metallisations and an integrated-circuit chip disposed on the second side of the metallisations, opposite to the first side, electrical interconnection elements, separate from the metallisations, directly connecting the chip and disposed on the second side of the metallisations, wherein the electrical interconnection elements are produced on a single-face module.

13. A method according to claim 12, wherein the interconnection elements extend on or above or along an interconnection zone.

14. A method according to claim 12, wherein the interconnection elements extend outside the periphery of the module and wherein the elements are cut subsequently.

15. A method according to claim 12, wherein one end of the interconnection elements directly connects a pin of the chip by soldering while the other end is soldered to conductive pads or metallisations situated outside the limit of the module, through an orifice or connection well provided in a dielectric substrate.

16. A method according to claim 12, further comprising a step of at least partial enrobing of the chip by an enrobing and/or adhesive material with the exception of at least one portion of the interconnection elements.

17. A method according to claim 12, further comprising a step of forming interconnection pins from conductive material in the interconnection zone so as to electrically contact a portion of at least one interconnection element.

18. A method according to claim 12, further comprising a step of cutting the interconnection element while extracting the module from a strip.

19. A method for manufacturing an electrical and/or electronic device, said device comprising a support body and the module obtained according to claim 12, fixed to the support body, wherein the method comprises the following steps of: forming a support body having terminals of a second circuit accessible in/on the support body, transferring the module onto the support body, a first circuit of the module connecting said terminals of the second circuit.

20. A method according to claim 19, wherein the step of connecting the module to the terminals takes place during fixing of the module to the support body, wherein pins connect said terminals of the support body.

21. A method according to claim 20, further comprising a step of depositing conductive material on said terminals or tracks.

22. A method according to claim 12, wherein the interconnection elements are disposed solely within the periphery of the module.

23. A method according to claim 12, wherein the interconnection elements are held in place on or above or along an interconnection zone by adhesion.

24. A method according to claim 23, wherein the adhesion is effected via an adhesive for inserting the module or by thermocompression or thermoadhesion on an adhesive surface of the module.

25. A method according to claim 12, wherein said circuit comprises an antenna or a display or a keypad or a switch.

26. A module having an electronic chip, comprising: metallisations accessible from a first side of the metallisations and an integrated-circuit chip disposed on the second side of the metallisations, opposite to the first side, electrical interconnection elements, separate from the metallisations, directly connecting the chip and disposed on the second side of the metallisations, wherein the electrical interconnection elements are disposed on a single-face module.

27. A module having an electronic chip according to claim 26, comprising electrical contact pads accessible on a first face of a dielectric substrate and an integrated-circuit chip on the same side as a second face opposite to the first face, further comprising electrical interconnection elements connecting the chip and extending over/above/along the second face of the substrate.

28. A device comprising the module according to claim 26.

Description

BRIEF DESCRIPTION OF THE FIGURES

[0037] FIGS. 1 and 2 illustrate a smartcard module of the prior art respectively in plan view and in cross section;

[0038] FIGS. 3 and 4 illustrate a step of producing a module in accordance with an embodiment of the method of the invention according to two variants;

[0039] FIG. 5 is a view in partial cross section of a module illustrated in one of the previous two figures;

[0040] FIGS. 6 and 7 illustrate a step of depositing conductive interconnection material on the modules in FIGS. 3 and 4;

[0041] FIGS. 8 and 9 illustrate respectively a step of depositing conductive interconnection material and a step of cutting/extracting the module from a support strip according to a preferred embodiment of the method of the invention;

[0042] FIGS. 9A and 10 illustrate two variants of the formation of interconnection elements;

[0043] FIG. 11 illustrates a transfer and connection of the module with interconnection terminals disposed in a support body;

[0044] FIG. 12 illustrates a variant embodiment of interconnection elements with conductive flexible blades;

[0045] FIGS. 13 and 14 illustrate respectively the deposition of conductive material on end portions of conductive tracks in a cavity of a support body before transfer and connection of a module according to another electrical interconnection mode.

DESCRIPTION

[0046] FIGS. 1 and 2 illustrate a hybrid integrated-circuit smartcard module 7 of the prior art. It comprises contact pads 10, 11 on a dielectric or insulating support 20 in particular of the LFCC (lead frame chip carrier) type, at least one integrated-circuit chip 8 transferred onto the support 20 or here onto a metal pad, for contact or not. The contact pads are intended to connect a smartcard reader connector.

[0047] The module also comprises connections 9 for in particular connecting contact pads by soldered wires, by conductive glue or the like, a chip being able to be turned over (flip-chip) or not. It comprises an enrobing of the chip and/or of its connections with a protective material 14 such as a resin (glob-top), which can be deposited for example in drop form or deposited by overmoulding.

[0048] The connections 9 connect the contact pads through orifices 22 formed in the insulating support.

[0049] The bottom surface of the module extending substantially from the edge of the enrobing as far as the edge of the module can constitute a surface for bonding the module to a surface of a cavity provided in the card body.

[0050] The module also comprises connection means 24 for connecting an antenna embedded in a card body (not shown) receiving the module. These means 24 connect two conductive pads 11 of the module through two orifices 23 situated in the surface bonding the module to the card body or at least outside the protective material 14. These two pads 11 are connected to the radio-frequency pins of the chip, here by soldered wires through orifices 23.

[0051] FIGS. 3 and 4 illustrate a step of producing a module 27 with chip 8 according to a first embodiment with two variants.

[0052] According to one feature of a preferred method for manufacturing a device comprising an electronic-chip module (17) according to the invention, the method comprises a step of producing metallisations (or electrical contact pads) accessible from a first side of the metallisations. Here metallisations are produced on a first face of a dielectric substrate. The method also comprises a step of transferring an integrated-circuit chip onto the second side of the metallisations, opposite to the first side. The elements may extend over/above/along the metallisations (the case of metallisations with dielectric or metallisations supported by a dielectric perforated at the contact pads, the metallisations being behind the dielectric substrate on the same side as the chip intended to be buried in a card body). When a dielectric substrate is present, the interconnection elements may extend along/over/above the dielectric on the second side opposite to the first side of the metallisations. The elements may therefore extend over/above/along the metallisations or a dielectric substrate according to circumstances. Here, in the example, the chip is disposed on the same side as a second dielectric face opposite to the first face. The chip is in principle connected to the contact pads (or metallisations) by soldered wires.

[0053] The same references from one figure to another indicate identical or similar means. The module is formed on a strip 37 of insulating dielectric film comprising metallisations defining a plurality of module locations. The metallisations are laminated or etched in a known fashion on a face of the dielectric. Alternatively, the module may be formed on a sheet of dielectric film instead of a strip.

[0054] The module 27 with integrated-circuit or electronic chip 8 may be substantially of the same type as in the previous figures with the exception of interconnection elements extending from the chip towards the periphery of the module and separate from the first metallisation.

[0055] It comprises here a substrate 20 a preferably a protective material 14 at least partially enrobing the electronic circuit 28 in an enrobing zone 14E. The enrobing zone 14E is surrounded by a peripheral surface 14C for fixing the module or for bonding.

[0056] The electronic chip 28 connects contact pads 10 through orifices 22 by any known means and in this case by soldered wires.

[0057] The chip 8 preferably fulfils functions of communication with a contact and contactless reader. It comprises pins for ISO 7816 contact-type communication and two pins for contactless communication.

[0058] However, the chip may make an interconnection with a circuit other than an antenna disposed in a support body such as a display, a keypad, a switch, etc.

[0059] The chip is mounted here normally on the module by having its rear face fixed to the module as in FIG. 1. Its active face carrying its electrical connection pins is oriented towards the outside of the module.

[0060] In a variant of the invention, the absence of a substrate 20 can be envisaged, the pads or metallisations then being held together via an enrobing or a resin.

[0061] According to one feature, the method comprises the step of forming electrical interconnection elements (9C, 19C, 30) connecting the chip and extending over/above the second face of the substrate or metallisations without electrically connecting the metallisations at least in the bonding zone of the module (situated at the periphery of the enrobing).

[0062] In the example, FIGS. 3 and 4, the interconnection elements according to the preferred mode are produced in the form of conductive soldered wires 9C. One end of these wires directly connects a pin of the chip 8 by soldering while the other end is soldered to contact pads (or metallisations) situated outside the limit of the module 27, through an orifice (or connection well) 22C, 22L provided in the dielectric substrate.

[0063] The elongate soldering wells 22L make it possible to use a greater variety of configuration of chip pins.

[0064] According to a feature of one embodiment, the interconnection elements 9C, 19C extend in the direction of or outside the periphery 27 of the module; these interconnection elements are cut subsequently in particular to the cutting of the module from its reel support strip 37.

[0065] In the example, the soldered wires 9C of the contactless pins extend beyond the finite limit of the module 27 in order to be soldered in wells 22C situated outside the limit of the module. This zone Zt outside the zone of the module 27 corresponds to a working or current-feed zone particular to the module strip 37.

[0066] According to a preferred feature, the method may comprise a step of at least partial enrobing of the chip, with an enrobing material with the exception of at least one portion of the interconnection elements (extending in the interconnection zone Z).

[0067] In the example in FIGS. 3-5, the chip and its wired connections 9 of the contact type are enrobed. Likewise the starting portions of the contactless communication wires 9C are enrobed. The residual portion extending from the enrobing resin as far as the waiting wells 9C is not enrobed with the insulating enrobing resin.

[0068] According to another feature of the preferred embodiment, the method may comprise a step of forming interconnecting pins 30 from conductive material in the interconnection zone so as to trap/electrically contact a portion of at least one interconnection element 9C, in the interconnection zone Z.

[0069] In the example in FIGS. 6 and 7, a deposition is effected of at least one drop of conductive material 30 comprising in particular silver particles on top of each conductive wire 9C. Each drop forms a pin resting on the dielectric substrate 20 and extending at a height while trapping and contacting each conductive wire 9C.

[0070] The function of the wells 22C or 22L is therefore to fix the wires 9C temporally in position in the interconnection zone, at least during the enrobing step or at least during the formation of the conductive pins. Once the enrobing has been carried out or at least the conductive pin 30 formed, the conductive wires 9C are held mechanically substantially in position on a path passing through an interconnection zone “Z”.

[0071] This is because, during manipulations of the strips 37 during manufacture, it may happen that the conductive wires 9C not held mechanically move into undesired positions under the effect of the movements or vibrations caused by the movement of the modules from one manufacturing operating gate to another.

[0072] As indicated, it is possible to overcome this problem by increasing the number of soldered wires on the same pin and placing a plurality of wire passages in the interconnection zone “Z”. In this way the chances of holding at least one wire in the interconnection zone “Z” are increased. The increase in number of the wires on the same chip pin also improves the electrical contact with the silver particles of the pins 30 of conductive material.

[0073] Alternatively, generally to fix the end (in principle free) of the interconnection elements, in the case where an insertion adhesive is deposited on the module at least in the module bonding zone, the wires of the interconnection elements 9C can be held by adhesion to the adhesive in particular in the interconnection zone “Z”.

[0074] According to another feature of the preferred embodiment, the cutting of the interconnection element is carried out during the step of extraction/cutting of the module from the substrate.

[0075] In the example in FIG. 9, the conductive wires 9C are cut (broken line D) during the extraction and transfer of the module.

[0076] Alternatively, in FIG. 10, the wires can be cut before the extraction of the module, in particular after the formation of the conductive silver pins (FIG. 9A).

[0077] Alternatively (FIG. 10), the wires 9C can be formed so as to terminate in or pass through the interconnection zone (Z) without being soldered in a well 22C. Before the enrobing, the wires undergo curvature or bending given by the soldering machine so as to have an end adjoining the surface of the insulating substrate.

[0078] The module can thus remain (illustrated in FIG. 10) before interconnection in particular by transfer into an accommodating cavity of a support body; or, as illustrated in FIG. 9A, the module may also and preferably receive conductive interconnection pins 30 formed by the deposition of conductive material. This has the advantage of holding the wires 9C in place and preparing a subsequent interconnection.

[0079] In general it is possible to use more rigid conductive wires or interconnection elements, in particular in the form of a blade, or by duplicating or tripling the wires 9C on the same pin (not shown).

[0080] Thus, for example, as illustrated in FIG. 12, it is possible to use interconnection elements in the form of a conductive layer/blade for greater rigidity or mechanical strength. These conductive layers may for example be 0.05 mm to 0.5 mm wide.

[0081] A conductive strip may be directly soldered to a conductive bump formed on a contactless pin of the chip. The other end of the strip may be held in the air or be soldered or fixed outside the zone of the module. A cutting of this fixed strip outside the zone of the module may occur subsequently at the same time as the cutting/extraction of the module of the continuous support (lead frame).

[0082] In FIG. 12, a flexible blade 19C connects the chip via a first electrical connection relay well 22C (preferably situated in an enrobing zone for receiving a protective material (resin)) adjacent to a peripheral bonding zone of the module and interconnection zone “Z”. A blade is soldered by its ends to two wells 92C (accessing metallisations 10) situated respectively in the zone 27 of the module and outside the zone 27 of the module.

[0083] Where applicable, each blade (with a cross section two to ten times wider than the diameter of a soldered wire) may be directly connected to a chip pin. The pin of the chip is typically 50 μm to 100 μm in size. These blades/strips have dimensions of between 0.1 mm to 0.5 mm and may be soldered to a bump previously produced on the pin. Thus the electrically conductive blade (or electrically conductive strip) that is wider can connect this small pin.

[0084] Preferably, the blade is placed (or even lightly bonded) to the dielectric in the vicinity of the base of the chip. An interconnection wire can connect a chip pin by soldering and each blade also by soldering, to the base of the chip. The other end of the blade may be fixed by soldering to a relay or working pad in a well 22C outside the surface of the module. This end will subsequently be cut with the extraction of the module for insertion thereof.

[0085] The connection of the soldered wire to a blade can preferably be enrobed with enrobing material 14 for better strength and mechanical protection of the assembly. The blade 19C is held in position mechanically by virtue of the enrobing 14 and/or optional adhesion of an end on the dielectric in the immediate vicinity of the chip in the zone 14E.

[0086] The latter embodiment avoids having relay conductive islands in the wells 22C (a source of short-circuit accessible from the outside) formed in the metallisations 10.

[0087] Alternatively, the conductive wires 9C may be fixed to the dielectric substrate itself by thermocompression or thermoadhesion. The substrate may have a surface cladding offering an adhesive property in order to make the wire 9C or blade 19C adhere.

[0088] Thus the wire may be held in place in the interconnection zone without having to be extended outside the zone 27 of the module.

[0089] According to one feature of the preferred embodiment of the invention, the module is connected to the connection terminals 32 of a support body during the fixing of the modules in the support body 40 (FIG. 11).

[0090] In FIG. 11, the module is illustrated in position in a cavity of a support body, in this case a smartcard body.

[0091] The conductive pin 30 of the module electrically contacts, by resilient deformation, end portions 32 of an electrical circuit (here an antenna) situated in the support body 40. The electrical connection is made by simple transfer of the module into the cavities 33 and 31. The module is fixed by an adhesive 33.

[0092] The invention provides a method for manufacturing an electrical and/or electronic device comprising the previously described module.

[0093] The device may comprise a support body 40 provided with at least one cavity 31, 33 provided in the support body, and the module is fixed in the cavity.

[0094] It is possible first to form a support body 40 having terminals of a second circuit 32 incorporated in the support body and at least one cavity 31, 32 provided above the connection terminals 32 of the second circuit so as to reveal said terminals 32 or to make them accessible.

[0095] Next, the module is transferred into the cavity, which connects the terminals of the second circuit.

[0096] Alternatively (FIGS. 13 and 14), conductive material is deposited on end portions 32 of the support body situated in a cavity of the support body 32, 32.

[0097] The module transferred into the cavity 31, 33 may be in accordance with any of the embodiments described previously. The module comprises interconnection zones Z comprising conductive interconnection elements 9C, 19C, 30 held in this zone either alone (being connected to the chip) or by being captive in a conductive pin 30 or an enrobing material deposited close by.

[0098] The invention thus produces interconnection zones “Z” distinct from the metallisations situated on a first face of the module (in particular those intended to connect a contact card reader). These interconnection zones advantageously use conventional interconnection elements, in particular a conductive wire 9C, identical to those used for connecting the chip to the metallisations of the module.

[0099] The chip may also be mounted turned over (flip-chip). Interconnection wires can be welded to metal relay zones or redirection tracks situated in the vicinity of the location of the chip in the zone 14E (outside a zone of bonding of the module in a support body).

[0100] The conductive wires 9C may extend from the relay zones towards the periphery of the module while remaining suspended in the air awaiting an interconnection with end portions of a support body.

[0101] Preferably, conductive pins 30 trapping these wires as before are formed. Alternatively, conductive blades 19C more rigid than the wires are used in order to remain in the air during the time of an interconnection; it is also possible to solder a plurality 9C of wires on the same relay zone in order to facilitate interconnection.

[0102] Where applicable, in normal mounting or in flip-chip mode, the invention makes provision for forming one or more loops starting from a chip pin or a relay pad passing over an interconnection Z and returning to the starting point, for soldering to the chip pin or relay pad.

[0103] The loop may receive a conductive material in the form of a pin at the interconnection zone Z.

[0104] In this way loops or lugs issuing from the chip pins are produced, which have the advantage of having better mechanical strength than a single wire with a free end in the air.

[0105] The mechanical strength of the interconnection elements 9C, 19C is important in order to ensure a good electrical connection (and correct positioning of the interconnection elements) when the module is transferred and connected to terminals of a support body.

[0106] Where applicable, the invention makes provision for interconnecting the module with a second circuit formed against or on the insulating substrate 20. The circuit may for example be an antenna formed by printing conductive material.

[0107] The module is therefore not necessarily inserted in a support body.

[0108] Alternatively, the metallisations may be disposed on one or other face of a dielectric film. In the case where these metallisations are disposed on a rear face of a support film (the face intended to be against a support body), openings make it possible to access these metallisations.

[0109] Where applicable, the interconnection elements are produced as previously described but in addition an insulating material is disposed in the interconnection zone Z in order to insulate metallisations situated vertically in line with the conductive wire or conductive blades.