EP2537400A1

EP2537400A1 - Method for manufacturing an electronic package

Info

Publication number: EP2537400A1
Application number: EP11703690A
Authority: EP
Inventors: Lucile Dossetto; Jean-Christophe Fidalgo; Béatrice Dubois
Original assignee: Gemalto SA
Current assignee: Thales DIS France SA
Priority date: 2010-02-16
Filing date: 2011-02-15
Publication date: 2012-12-26
Also published as: CN102754535A; BR112012020492B1; EP2357875A1; WO2011101359A1; CN102754535B

Abstract

The invention relates to methods and systems for manufacturing packages or modules comprising one or more electronic elements. Such methods and systems are particularly effective and adaptable because said methods and systems employ mainly techniques involving sprays of insulating or conductive materials.

Description

Method for manufacturing an electronic box

The invention relates to a system and a method for manufacturing an electronic box comprising a chip and / or an electronic component and the housing obtained.

Such boxes can be found for example in the form of smart card modules, form factors such as small electronic objects of micro-SD (Secure Digital in English) formats, Micro-SIM (Subscriber Identity Module in language). English) or SIM plug-in, Mini UICC (Universal Integrated Circuit Card in English). We can also find a range of housings for mounting surface components (SMD or SMD) and BGA (Bail Grid Array English language) with connection balls.

The invention relates more particularly, but not limited to, the manufacture of secure portable electronic objects which find their particular applications in health, banking, telecommunications or identity control.

Known techniques for making such objects require a process that is sometimes slow, complex and not very adaptable.

For example, to manufacture a module for a smart card, steps are required among which are mainly:

a definition of a specific printed circuit board; mechanical cutting of said printed circuit or chemical etching to define a form of contacts;

cutting in an electrical to create connection wells;

a backing of the dielectric on the printed circuit; metallization of contact pads;

a gluing of one or more chips of variable thickness;

wiring using wires to interconnect said chips and connect the contact points;

a coating under a protective resin, etc. To make an electronic object, it is also necessary to postpone a module within a cavity provided in a plastic body for example. Including for very small objects, it is thus necessary to provide the creation of a body in parallel with the creation of a module and a postponement of the latter in said body, etc.

All of these techniques require dedicated tools that must be adapted to a particular module or box. To maintain an acceptable manufacturing rate, the machines require high precision and are therefore expensive. For example, a cabling operation is particularly problematic: from a few wires for everyday products to about a hundred threads for complex products, usually gold or aluminum, are sometimes necessary for the realization of a module. Similarly a gluing operation can be sensitive especially if a plurality of separate components or chips are needed to make a module. Homogeneous bonding of chips of various thicknesses or electronic components - such as capacities for example - can be complex to prevent the formation of air bubbles, trapped under some chips, which would weaken the module. The manufacturing time can be penalizing and alter the overall cost of manufacturing a housing.

The invention makes it possible to respond to all the drawbacks raised by the known solutions. It allows in particular to use a minimum of equipment and elements to form a housing. The invention maintains a high level of requirements for the protection of chips and electronic elements. The invention also simplifies the connection step and eliminates a series of expensive or time-consuming operations.

The invention makes it possible to implement a reliable, fast and adaptable manufacturing process. The invention further allows the direct realization of a form factor in a single series operations.

To this end, there is provided a method for manufacturing an electronic box comprising a chip or an electronic component whose one face is active at least one contact or contact pad, said method comprising: - a step to deposit the stain), active face down an adhesive support;

a step of molding a resin for coating the chip (1) on its adhesive support, the chip and resin assembly forming an island;

- A reversal step of said island so that the chip of the latter has its active face exposed;

a step for applying a conductive material on the returned island, to materialize a circuit element or a contact pad;

characterized in that the support is a towed adhesive support and that the material is applied directly by jet of material, inkjet or screen printing on at least the contact or contact pad and the island.

According to a preferred embodiment, an island may comprise a plurality of chips and / or electronic components. The step of applying a conductive material may further include interconnecting said chips and / or electronic components.

The invention provides that such a method may comprise a step - prior to the step for applying a conductive material - to apply an insulating layer on the returned island, with the exception of one or more contact pads of a chip of the island.

Alternatively, the method may comprise a step - prior to the step for applying a conductive material - to remove a portion of an insulating layer at a contact pad of a chip of the island, said insulating layer being previously transferred from the adhesive support to the island during the steps to deposit the chip and to mold the resin.

Whatever the embodiment, a method according to the invention may comprise a step - subsequent to the step for applying a conductive material - to apply an insulating layer on the returned island with the exception of a contact pad the island or a cutting step of the island to adapt the dimensions of the latter.

The invention also provides a system for manufacturing an electronic box - comprising a chip of which one face is active -, said system comprising: - Means for depositing a chip - active face downwards - on a towed adhesive support;

means for molding a resin for coating the chip on its adhesive support, the chip and resin assembly forming an island; - Means for returning said island so that the chip of the latter has its active face upwards;

- Means for applying a conductive material on the returned island, to materialize a contact area connecting a contact pad of the chip to the outside world.

It may be provided that such a system may also include:

means for applying an insulating layer to all or part of the returned island;

means for cutting the island;

- Or control means for implementing a method according to the invention.

Similarly, the invention relates to an electronic box comprising at least one chip or electronic component whose face is active with at least one contact or contact pad, comprising:

- A molding (S2) of a resin coating the chip forming an island, the chip of the latter having its active face exposed;

a conductive material on the island, to materialize a circuit element or a contact pad;

The housing is characterized in that the material is applied directly by jet of material, inkjet or screen printing on at least the contact and / or the contact pad and the island, to form at least one electrical circuit element or a contact area.

Preferably, the chips have different dimensions (height, thickness and / or width and / or length) and / or of different type (for example, ISO 7816 electrical contact chip and radio frequency chip).

Preferably, the chips have a thickness different from one another, the thickness being defined between their active face and opposite rear face.

Preferably, the chips have their active face substantially at the same level in the block relative to each other while their rear face is at the same level in the block. Preferably, the housing comprises a bare chip coated with a material and connected to any component (chip or component already packaged or otherwise coated) and further packaged by the same material above. The method thus has the advantage of connecting components of different shape and or presented at different stages of finishing or coating (already coated, partially or not at all).

Other features and advantages will emerge more clearly on reading the following description and on examining the figures that accompany it, among which:

- Figures 1 and 2 show a method of manufacturing an electronic box according to the invention;

- Figures 3a and 3b show a variant provided by the invention for applying a first insulating layer on an island.

Figures 1 and 2 show a system and a manufacturing method according to the invention.

Thus, according to FIG. 1, from a sawed 1 W (or wafer in English) silicon wafer comprising a plurality of chips having undergone a preparation making it possible to obtain, on the surface of the connection pads, an inert conductive layer , a first step S1 - of a method according to the invention - consists of depositing a chip 1 (from the slab) on an adhesive support 2 - such as an adhesive tape. The carrier 2 is preferably pulled to convey the chip - as indicated by the arrow D. The chip 1 is deposited on the adhesive support 2, the active face of the chip pointing downwards. Thus, said active face is directly in contact with the adhesive support 2. To represent an active face, Figure 1 describes a chip 1 having two contact pads 1 a visible and present on said active face.

In addition to a first function of conveying a chip, the adhesive of the support 2 makes it possible to maintain it during the first stages of the manufacturing process. According to a preferred embodiment, the adhesive hes 2 support is an adhesive strip whose width is 35 or 70 millimeters in order to be compatible with many equipment used, according to the state of the art, in the industry. Smartcard. Furthermore, the invention provides the manufacture of housings or modules respectively comprising one or more chips per housing or module. Such a device may even include an electronic component such as a capacitor for example, or a resonator. To simplify the presentation of the invention, we will first describe a first embodiment in connection with Figures 1 and 2, for which a housing has only one chip 1. Other examples of applications will be described later.

According to this first example, a chip 1, deposited in step S1, moves with the aid of the adhesive support 2 to reach the vicinity of means 20 provided for molding a resin 3 around said chip 1. The second step S2 of the method can thus consist of a molding-transfer of a resin 3 applied around and on the non-active face of the chip. This resin 3, hardening, provides protection to the chip. It can also constitute the support or even directly the body of an electronic object such as, for example, a mini-UICC card. In the latter case, the thickness of the resin 3 is sized to meet the dimensional criteria of said object.

In connection with FIG. 1, the invention provides a variant for which S2 is applied to a resin 3, not only on a chip but also on a plurality of chips. We thus obtain a set "resin 3 plus chips 1" constituting what we will call an "island". We will see later that it is possible, at the end of the manufacturing process - by a division operation of said island - to find, not a single box, but a set of boxes from the same island. The shape of the island can be adapted to the chosen configuration.

The molding applied to the non-active face of the chip while it is positioned on the support 2 is particularly advantageous: it does not weaken said chip. In addition, see above, after turning the island to expose the active face of the chip upward, this molding technique allows to have islands whose active faces of the chips are flush and at the same level as the surface upper resin 3 forming the island.

Step S3 of a method according to the invention thus consists in returning an island conveyed by the adhesive support 2 so that said island exposes the active faces of the chips. The invention provides different techniques for performing island rollover. A preferred embodiment is S3 to use a second towed adhesive medium 30 whose tack properties are 2. Such a support 30 - such as, for example, a band of a width comparable to the band 2 of FIG. 1 - is applied to the back of an island conveyed by the support 2. contact carrier 30 on the island, causes the detachment of the latter support 2 and thus the flipping of the island since the latter is now véh iculé on the support 30, the active faces of the exposed chips. In a variant, the invention provides that the reversal step S3 may consist of using a gripping tool to grip an island conveyed on the adhesive support 2, detach it from the latter, turn it over and deposit it, the active faces of the chips exposed on it. a support 30, such as an adhesive tape or a honeycomb support or any other type of support adapted to convey an island thus returned. Any other technique for returning an island could also be implemented according to the invention.

The invention provides that the support 2 may be in the form of a consumable type band: it serves only a single pass. Alternatively, the invention provides that such a strip can be unwound at the beginning of the process and rewound at the end of step S3 so that the band can be reused a second time. A continuous band could also be exploited provided that the adhesive properties thereof remain sufficient to provide the functions of maintenance and conveying.

FIG. 2 illustrates the subsequent steps of steps S1, S2 and S3.

Thus the invention provides that an island 10 is conveyed on a support 30 in a direction D. In step S4, such an island is in the vicinity of means 41 for applying to the island 10 a layer of insulating material 4 Preferably, this layer does not completely cover the surface of the island 1 0 to leave at least one contact pad 1, a chip not covered by said insulating layer. It is thus possible, for example, to render inoperative a contact pad serving essentially to perform electrical tests upstream of the manufacturing method according to the invention. By way of example, the means 41 may consist of a print head of an insulating ink. In a variant, the means 41 are capable of producing a jet of an insulating material on said island. To harden the deposited material 4, the use of a lamp or an ultraviolet diode 42 may be provided to irradiate the material 4 if it is sensitive to ultraviolet, for example. Any other technique adapted to the insulating material could however be implemented at S4 to fix the layer 4. The invention provides that this step may be optional. Thus, one can imagine that the active face of a chip has already been treated beforehand. The invention also provides that step S4 may be preceded by a step (not shown in FIG. 2) for depositing, on the active face of a chip 1 and / or on resin 3, a primer to facilitate the hangs up materials to drop.

The following step S5 consists of depositing a conductive material 5 mainly to constitute a contact pad in connection with a contact pad 1a. For this purpose an island is positioned, via the support 30, close to means 51 for projecting said conductive material 5. If necessary, this step may consist in iterating several material removal steps 5 according to the thickness and / or the required reason. According to a preferred embodiment, the means 51 are a print head - with numerical or piezoelectric control - capable of printing a conductive ink as a material 5. This embodiment is particularly advantageous because it is very easily adaptable to the topography of the plots of the chips. Other digital printing techniques could be used to deposit conductive inks such as, for example, aerosol ink deposition. Optionally, the means 51 are associated with means 52 for adhering and facilitating the conductivity of the deposited conductive material. Thus the means 52 can implement a pressure and / or heating action to cause the coalescence of nanoparticles contained in a conductive ink 5.

Contact pads and / or electrical circuit elements may comprise or consist of nanoparticle particles.

Alternatively, the means 52 may facilitate the removal of a jet-promoting solvent from an ink or conductive material by heating, for example, an island or drawing hot air thereon. The invention provides the use of any means adapted to fix the conductive material 5 and promote conductivity.

FIG. 2 illustrates a subsequent and optional step S6 making it possible to deposit a second layer of insulating material 6. For this, the island is positioned near means that are similar or identical to the means 41 and 42 described in connection with step S4 of FIG. process. This step makes it possible to isolate connection tracks made with conductive material 5, tracks that one does not wish to expose. It is thus possible to let appear contact pads, flush with the surface of the island, respectively connected to the pads 1a of the chip 1. Likewise, in general, insulating material arranged in a layer on the islands may be constituted or comprise insulating nanoparticles.

The invention provides that an optional step S7 is implemented to cut an island. FIG. 2 shows an embodiment for which the island is positioned near lasers 71. Under the action of a laser beam island 10 is cut precisely to the required dimensions. In a variant, in the case where - as illustrated in FIG. 2 - an island comprises a plurality of chips, this step S7 makes it possible to individualize several sub-islands 10a, 10b, 10c from the island 10. We can from this how to factor the production of a set of modules or boxes to optimize the manufacturing time and split at the end of the process modules or modules. Other cutting techniques could be used: water jet, mechanical machining, diamond saw, etc.

The invention preferably provides that inks can be used to make the insulating, conductive or bonding primer layers. The use of print heads, numerically controlled or piezoelectric, thus offers a very high flexibility of implementation and a great ease of adaptation. The means 42, 52, 62 are adapted to the type of ink used: infrared lamp or diode, ultraviolet, pulsed hot air, microwave, oven, etc.

The invention provides, alternatively, that printing techniques, such as screen printing, pad printing or any other printing technique can be used in addition to or in lieu of an inkjet or material.

The implementation of a method and a system as described in connection with FIGS. 1 and 2, also makes it possible to produce modules or packages comprising several chips and / or electronic components - such as capacitors, resonators, etc.

To make such boxes, it is difficult and expensive, using known techniques, to implement manufacturing processes that are both fast, adaptable and reliable. It is, for example, tricky to connect chips with gold threads, to stick chips with dimensions (especially the thickness) are variable, to prevent the risks of short circuits, etc.

The invention removes all these disadvantages and allows a fast, reliable and adaptable process. Thus, in conjunction with FIGS. 1 and 2, step S1 may consist in depositing, on the adhesive support 2, a set of chips and / or components necessary for producing a housing. The adhesive of the support 2 makes it possible to ensure the topography of the various electronic elements. Step S1 may also make it possible to deposit a plurality of component assemblies in order to factorize the manufacture of a plurality of packages.

A step S2 makes it possible to mold in the same island all the electronic elements - or even a plurality of sets. During the turning step S3 of an island, the active faces of the chips and / or electronic components are all flush and at the same level as the upper surface of the resin 3. Thus, the risks associated with an alignment imperfect or defective chips, the presence of trapped air bubbles (etc.) are removed. Thanks to the invention, an island is perfectly rigid and easily reproducible. Step S5 of a method according to the invention makes it possible, besides materializing contact pads, to make all the connections between the electronic elements: more gold wires, less scrap associated with faulty wire connections, etc. . If necessary, insulating and conductive layer deposition steps may be repeated to achieve a complex topography (or layout in English). Thus, the steps S5 and S6 can be repeated as much as necessary to achieve a crossing of conductive tracks for example. According to the invention, it is possible to implement a step for developing an antenna connected to one or more electronic elements using techniques such as those previously described.

A step of type S7 makes it possible to individualize modules or housings thus manufactured. It can make it possible to refine the cut of said module or box according to strict standardized criteria.

The invention provides an alternative embodiment as shown in connection with Figures 3a and 3b.

This technique offers an alternative to the step S4 described in connection with FIG. 4. Thus, instead of depositing an insulating ink 4, FIG. an adhesive support 2 comprising a thin layer of insulating material 2a. During the steps for depositing S1 a chip and for molding S2 the resin 3, the insulating material 2a is thus applied to the island.

During the reversal step S3, an island is detached from the support 2 but the layer 2a remains present as shown in Figure 3b. It is thus transferred from the adhesive support 2 to the island 10. In order to keep a contact pad 1a (or several) not covered with material 2a, the invention provides that part of said insulating layer 2a can be eliminated using various techniques (laser, thermal, ultraviolet, etc.). Fig ure 3b thus has an island 10 whose contact pads 1 has chips 1 are thus released.

Such an island deposited on a support 30 can be treated subsequently according to the steps S5 to S7 as described previously with reference to FIG. 2.

According to another variant, the invention provides for integrally keeping the film 2 applied to the islands and to pierce it at the pads so as to have a large protective layer above the chips or components.

The invention also provides, in order to facilitate the step S3 of molding the resin 3, to use a mold whose walls coming into contact with the adhesive support 2 are treated (for example with teflon) in order to reduce the adhesion. of the latter on the support 2. Alternatively, the adhesive support 2 may be devoid of adhesive material on outer strips so that the mold does not come into contact with said adhesive material.

The invention has been described and illustrated in the field of manufacturing modules or electronic boxes operated in the chip card industry. The invention can not be limited to this single application example but can also be applied to other fields and technologies.

Thus, the invention generally relates to a method for manufacturing an electronic box (10a, 10b, 10c) comprising a chip (1) whose active face comprises at least one contact pad (1 a), said method being comprising the steps following:

- Fixing (S1) a chip (1) on a support (2), its active face being oriented towards the support; - overmolding (S2) a material (3) on the chip (1) for coating the chip on its support (2), the chip and resin assembly forming an island or an electronic block (10);

- turning (S3) of said island or block so that the chip (1) has its active face exposed to the outside;

- Application (S5) of a conductive material (5) at least on a contact pad (1 a) of the chip to form at least one electrical circuit element.

The support is not necessarily towed, it can be supplied in plate. The chips can be fixed by any means on the support: adhesive or mechanical or physical attachment means.

If necessary, it eliminates adhesive support, the chips being placed on a support or overmoulding tray.

Claims

A method for manufacturing an electronic box (10a, 10b, 10c) comprising a chip (1) or electronic component whose one face is active at least one contact or contact pad, said method comprising:

a step (S1) for depositing the chip (1), active face downwardly an adhesive support;

a molding step (S2) of a resin (3) for coating the chip (1) on its adhesive support (2), the chip and resin assembly forming an island (10);

- a reversal step (S3) of said island so that the chip (1) of the latter has its active face exposed;

- a step for applying (S5) a conductive material (5) on the island (10) returned, to materialize a circuit element or a contact pad;

characterized in that the support is a towed adhesive support (2) and in that the material is applied directly by jet of material, inkjet or screen printing on at least the contact or contact pad and the island.

Method according to Claim 1, characterized in that the island (10) comprises a plurality of chips (1) and / or electronic components and that the step (S5) for applying a conductive material ( 5) further comprises interconnecting said chips and / or electronic components.

Method according to any one of the preceding claims, characterized in that it comprises a step (S4) - prior to step (S5) for applying a conductive material (5) - for applying an insulating layer (4) to the returned island (10) with the exception of one or more contact pads (1 a) of a chip (1) of the island.

Method according to claim 1 or 2, characterized in that it comprises a step - prior to step (S5) for applying a conductive material (5) - to remove a portion of an insulating layer (2a) at the level of at least one contact pad (1 a) of a chip of the island (10), said insulating layer (2a) being previously transferred from the adhesive support (2) to the island during the steps for depositing (S1) the chip and for molding (S2) the resin (3).

Method according to claim 1 or 2, characterized in that it comprises a step - prior to step (S5) for applying a conductive material (5) - to eliminate a part of the towed adhesive support (2) - forming a layer insulating - at least one contact pad (1 a) of a chip of the island (10), said adhesive support (2) remaining applied to the island at the end of the steps for depositing (S1 ) the chip and to mold (S2) the resin (3).

Process according to any one of the preceding claims, characterized in that it comprises a step (S6) - subsequent to the step (S5) for applying a conductive material (5) - for applying an insulating layer (6) on the island returned (10) with the exception of at least one contact area of the island.

Method according to any one of the preceding claims, characterized in that it comprises a step - subsequent to step (S4) for applying a first insulating layer (2a, 4) - to apply, on the returned island, a conductive material for materializing an antenna connected to at least one contact area of the island.

Method according to any one of the preceding claims, characterized in that the turning step (S3) of the island (10) comprises applying to the island a second adhesive support (30) towed to detach the island from the first adhesive support (2).

Method according to any one of the preceding claims, characterized in that it comprises a cutting step (S7) of the island to adapt the dimensions of the latter. Method according to any one of the preceding claims, characterized in that it comprises a preliminary step for depositing on a contact pad (1 a) of a chip, a material for facilitating the cond uctivity between the l ed it plot and the conductive material (5) soon to be filed.

Method according to any one of the preceding claims, characterized in that the step (S4, S6) for applying an insulating layer (4, 6) consists of carrying out an irradiation (42) of the insulating layer applied to the island for stiffening said layer.

Process according to any one of the preceding claims, characterized in that the step (S5) for applying a conductive material (5) consists of depositing an ink requiring, after its deposition (51), a coalescence step (51) - if the ink comprises nanoparticles - or a step (51) for discharging a solvent - if the latter is present in the ink - or a step (51) for irradiating the ink if the latter is sensitive to ultraviolet. 13. An electronic box (10a, 10b, 10c) comprising at least one chip (1) or electronic component, one face of which is active with at least one contact or contact pad, comprising:

- a molding (S2) of a resin (3) by robbing the chip (1) forming an island (10), the chip (1) of the latter having its active face exposed;

- a conductive material (5) on the island (10), to materialize a circuit element or a contact pad;

characterized in that the material is applied directly by jet of material, ink jet or screen printing on at least the contact and / or the contact pad and the island, to form at least one electrical circuit element or a range of contact.

14. An electronic box (1 0a, 1 0b, 10c) according to claim 1 6, characterized in that the chips or components have different thicknesses between them. - An electronic box (10a, 10b, 10c) according to claim 14 or 15, characterized in that said conductive material comprises or consists of nanoparticles.