FR2903624A1 - METHOD OF MANUFACTURING BY MOLDING A PORTABLE ELECTRONIC ENTITY, AND ENTITY THUS OBTAINED - Google Patents

Abstract

For the manufacture by molding of a portable electronic entity, a support provided with at least one component is placed along a wall of an open mold cavity, and a first mass of resin is cast along this support. the set thus obtained is placed in another open mold cavity, a second resin mass is cast along the support, for example the same as before, which is cured. The support advantageously comprises projecting parts, for example component parts projecting from the support. The portable electronic entity may be a microcircuit card or a USB key, in particular.

Description

TECHNICAL FIELD OF THE INVENTION The invention relates to a method of

  manufacturing by molding of a portable electronic entity comprising a substantially planar support having a plurality of components and / or having recesses or projections.  In particular, but not exclusively, it concerns the case where the portable electronic entity is a USB key or a microcircuit card, and particularly in the case where one of the components of this portable electronic entity is flush, for example a display or overflowing, for example a push button.  As we know, microcircuit cards have various formats, standardized or not (ID-1 or ID-000, in particular).  In various applications, these cards (ID-1 or ID-000 format above) have dimensions in accordance with ISO 7816, including a thickness of 0. About 76 mm.  In a variant, it may be, in particular, a card conforming to the MMC standard.  As for USB keys, they can have very different formats.  Among the components that may be desired to integrate into such a portable electronic entity, mention may be made of displays (or screens), batteries (or batteries), switches or pushbuttons, sensors (MEMS or others), keyboards, modules carrying a printed circuit and a microcircuit, etc.  It will be readily understood that a display, for example, is useful for enabling communication with the wearer, in market segments as diverse as authentication, personal credit, loyalty, e-commerce, transportation and the like. , identity verification, prepaid services or health.  A display allows you to display information such as: balance and balance of accounts, or exchange rates, or types of transactions, or loyalty points, or personal information, or photography, or the traffic status, or code, etc.  State of the art and problem to be solved Various techniques are known for making portable electronic entities.  Among these we can mention the technique of lamination of a support between at least two layers, and that of die casting.  The technique of lamination consists in preparing a support optionally comprising components and in pressing this support together with at least one other layer (in practice between at least two layers) so as to fasten this layer by pressure to this support (with possibly a contribution of heat).  However, this technique is incompatible in practice with a support which comprises a fragile component (such as a display or a battery) or a support whose face coming along the support is not flat (because of steps or because of the presence of 25 portions of projecting components) taking into account the risk of degradation of the support (especially if it is compressible) or steps or protruding portions due to the application of the lamination pressure (typically the order of 20 kg / cm 2) and / or temperature (typically between 130 C and 170 C) required.  Cold or low temperature lamination techniques (so-called warm lamination) have already been proposed, but these do not in practice make it possible to overcome the aforementioned drawbacks (temperatures or pressures remain critical).  It follows that this lamination technique in practice requires additional steps to implement components in that layer (or layers) located along the support.  As for the die casting technique, it has the advantage of using a molding resin which is in a liquid state, which allows a distribution of this resin in the available volume, without necessarily transmitting all of the pressure on the support.  In practice, the application of both a pressure and a heat input during molding is conventionally considered necessary to ensure a good distribution of the resin in the mold, in particular avoiding the formation of air bubbles. in the molded mass, especially when the resin has a significant viscosity.  One example is EP-0 914 921, which describes an injection molding process (therefore under pressure) in two stages and without support for the components.  More specifically, this document teaches to begin by injecting a first half of a card (this first half corresponds to a fraction of the final thickness) in a first cavity of a mold, to incorporate a winding by hot pressing. , then to inject the second half so as to trap the winding.  It should be noted that, in the case of injection molding, it may be difficult to keep in place the components to be integrated into the body to be produced, especially if they are fragile and / or if they are supported by a flexible support .  In addition, the above-mentioned pressure or temperature conditions may be incompatible with certain fragile components; for example, a battery that tolerates temperatures up to about 100 C can not withstand injection molding, typically employing temperatures of 200 C.  It follows that injection molding uses, like lamination, pressure and temperature conditions that may require additional operations to implement certain fragile components.  The invention aims to overcome the aforementioned drawbacks.  The subject of the invention is thus a method of manufacturing a portable electronic entity comprising components making it possible to set up these components very early in the formation of the body of this entity, without at the risk of subsequently degrading these components of the device. The application of a high pressure or temperature, while allowing for these components a support that can be both rigid and flexible, and while allowing at least some of these components are flush or overflowing.  Presentation of the invention The invention proposes a method of manufacturing a portable electronic entity comprising at least one component, this method comprising the following steps: preparation of a support provided with a component and having first and second components; second generally planar and parallel opposed faces, - placing said support in the open cavity of a first open mold in a configuration in which said support runs along its first face a wall of this open cavity, casting without pressure in this cavity of the first mold opening 20 of a first mass of resin along the second face of the support and then hardening of this first mass of resin so as to secure it to this second face, - placement of this support, with the first mass of resin, in the open cavity of a second open mold in a configuration in which this first mass of resin runs along a wall of the cavity of this second mold uvert, - casting without pressure of a second mass of resin along the first side of the support, then hardening of the second mass of resin so as to secure it to this first face.  It should be noted that pressure-free casting, as its name suggests, only involves ambient pressure, and furthermore only involves lower temperatures than injection molding.  Such a method thus makes it possible to manufacture by molding, without the high pressure or the high temperature, involved by injection molding, a portable electronic entity comprising a component that is sensitive to pressure or temperature, thanks to the fact that This component is carried or integrated into a support which can be rigid as well as flexible since it is sufficient for this support to be arranged along a wall of the cavity of a mold of appropriate shape.  As will be detailed later, this wall may be horizontal (ie be a bottom), or vertical or inclined.  According to a very advantageous characteristic, said support 10 comprises, with the component, a portion projecting from the first face of the support, said wall of the cavity of the first open mold against which this face comes into contact being shaped so as to have a depression opposite this protruding part when the support is in contact with this first face with said wall of the cavity of this first open mold, whereby the contact of the support with said wall of the cavity of this first open mold is essentially made at a distance from this projecting portion.  Advantageously, the support comprises, with the component, a portion projecting from the first face of the support, said wall 20 of the cavity of the first open mold with which this face is in contact being compressible so that to be able to adapt to this projecting part.  It should be noted that the projecting parts may be only localized, or on the contrary extend over a significant fraction of the support, in particular to an edge thereof.  More generally, in a preferred manner, said wall of the cavity of said first mold comprises means of adaptation to the presence of components on the first face (the compressible bottom, or the presence of the depressions, being only two of the possible forms possibly combined, of these means).  Thus, the support remains well parallel to said wall, or even to that which faces it, if it exists (which makes it possible to have a constant thickness for the portable electronic entity) and flat (including, for example, , when it is flexible), some are the projections present on the 2903624 6 support.  It is also avoided that the components are subjected to stresses by contact with said wall of the cavity (it is typically avoided that they are crushed).  It is thus understood that the projecting part is mechanically preserved when the support is in contact with said wall of the mold, which minimizes the risk of mechanical degradation during molding, including when it begins with the laying of the support by this face having the projecting portion.  This projection may, depending on the case, be part of the support itself (for example a local extra thickness) or be formed by a part of the component); this is particularly advantageous when the support or the component is made of a fragile material, for example when the support is made of a compressible material such as paper or cardboard or a deformable plastic material, or when the component is a display or a drums.  Even more advantageously, this protruding part, especially when it is formed by a component part, comes into flush (see overflowing or even further) of the free surface, that is to say that casting step of the second resin mass is carried out so that the free surface of this second mass of resin surrounds without submerging this projecting portion.  Of course, this projecting portion may alternatively be part of the support.  According to another advantageous characteristic, the support comprises at least one other projecting portion located on its second face, that is to say that the invention advantageously uses a support provided with parts projecting on its two faces.  Particularly advantageously, the general arrangement of the support is horizontal, that is to say that: the support is placed in the first open mold in a configuration in which it is substantially horizontal, said wall of the first open mold lengthened by this support being the bottom of the cavity of this first open mold, and the first mass of resin is poured without pressure into this cavity of the first mold open so as to form by this first mass of resin a first horizontal free surface , The support is returned after curing of the first mass of resin and then placed in the second open mold in a configuration in which it is substantially horizontal, said wall of the second open mold lined by the first mass of resin being the bottom of the cavity of this second mold 5 open, and the second mass of resin is poured without pressure in this cavity of the second mold open so as to cause this second resin mass to form a second horizontal free surface.  Advantageously, the support comprises, with the component, a protruding portion vis-à-vis the first face of the support, which comes flush or overflows, the free surface of the second mass of resin.  Also advantageously, the support comprises at least one protruding portion vis-à-vis the second face (in practice in addition to at least a first portion protruding vis-à-vis the first face), and Especially when it is formed by another component part, advantageously comes out flush or overflow of the free surface of the first resin mass, that is to say that the step of pouring of this first mass of resin is advantageously carried out so that the free surface of this first mass of resin surrounds without submerging this other projecting part; in addition, also advantageously, the bottom of the cavity of the second open mold is shaped so as to have a depression opposite this other part flush (or overflow) when the support is laid by the first mass of resin on the bottom of this second open mold, whereby support of the support, together with the first mass of resin, on the bottom of the second open mold is essentially made at a distance, laterally, of this portion flush.  More generally, the bottom of the cavity of said second mold advantageously comprises means of adaptation to the presence of components flush with (or exceeding) the surface of the resin disposed on the second face.  Thus, the support remains horizontal and flat.  It is also avoided that the components at least flush with (or exceeding) the surface of the resin disposed on the second face are subjected to constraints imposed by the bottom of the cavity.  These means of adaptation may be the depressions (or savings) mentioned above.  However, as a particularly advantageous variant, the bottom of the cavity of the second mold is shaped so as to be compressible with respect to this other portion flush (or overflow) when the support is placed on the bottom of this second mold .  Thus, either the first mold, the second mold or the two molds advantageously comprises adaptation means for accommodating at least a portion of said components, these means preferably comprising a compressible mold cavity bottom, and / or depressions.  Said compressible material is preferably an adhesive (such as acrylate).  This compressible material is advantageously carried by a support film along the bottom of the mold in question.  It follows from the abovementioned advantageous features that such a component projecting from the support, or flush with respect to the first mass of resin, is preserved from any mechanical degradation during the following pouring steps. and hardening.  This is particularly suitable for the case where the component is a display or a battery.  According to yet another advantageous variant, the projecting portion of the support is intended, not to be flush but to overflow, that is to say to project, vis-à-vis the body of the portable electronic entity that is to say that the first mass of resin only surrounds this projecting part, without adhering to it or coming to its level; one can mention the case of a push-button or a switch.  Advantageously, the support has, horizontally, a shape (or section) substantially equal to or identical to the shape of the bottom of the cavity of the first open mold, so that, when this support bears on the bottom of this cavity of the first open mold, the first resin mass has access only to the second face of the support, with low risk of bypassing the support and access to the first face.  Also, also advantageously, the support has, horizontally, a shape (or section) substantially equal (or identical) to that of the bottom of the cavity of the second open mold, so that, when the first mass of resin is pressed against the bottom of this cavity of the second open mold, the second mass of resin has access only to the first face of the support, with low risk of bypassing the support.  It is understood that, in this case, it is possible to use the same open mold for the two pouring and hardening steps (provided that the possible adaptations of the bottom for one and the other of the steps are compatible on the same background); However, it may appear advantageous to use two different molds, to allow, for example, a step of manufacturing a first entity (or group of entities) in the first mold at the same time as a manufacturing step another entity (or group of entities) in the second mold.  According to another variant which may have advantages, the support is smaller than the cavity of the first open mold. As a variant that is also advantageous, the support is smaller than the cavity of this second open mold, which allows the second mass of The resin protrudes laterally from the support and the first resin mass to a shape larger than the support.  It follows that the support may be smaller than the body of the electronic entity to be produced.  According to yet another variant, the support is smaller, at a time, than the first mold and the second mold, the support forming an interface between the two resin masses on only part of their facing surfaces (in this alternatively, the two molds can be formed of a single mold); in fact according to this variant, the first mass of resin can be used for the proper positioning of the support in the second mold.  Advantageously, the support comprises a plurality of components and, preferably, interconnections between these components.  In the case of the manufacture of a microcircuit card, it may be a central inlay, that is to say a support (generally less than 2903624 10 0 thickness. 25 mm, typically between 0. 04 mm and 0. 25 mm), for example plastic or paper advantageously carrying metal interconnections formed by a conventional technique (etching, deposit, etc.. ) between the components.  The resin masses advantageously have a respective thickness of between 0. 1 mm and 0. 38 mm.  These two resin masses preferably have equal thicknesses.  In one embodiment, the support carries a module provided with a microcircuit and external contacts.  In the case of the manufacture of a microcircuit card, the support is advantageously flexible.  Alternatively, the support is rigid, which is well suited to the manufacture of USB keys.  For this purpose, it is advantageous for at least one of the molds to comprise at least one movable lateral wall enabling a USB interface to be interposed between this movable side wall and the bottom of the cavity of this mold during casting of the mold. mass of resin in this mold.  Instead of having a generally horizontal configuration, the support can have a substantially vertical configuration, or inclined.  Thus, according to another advantageous variant of the invention, the wall of the cavity of the first open mold is a vertical side wall against which the support is maintained in a configuration in which this support is vertical.  The cavity comprises in practice an opposite wall, preferably flat and parallel to the contact wall; it is this opposite wall which defines the free surface of the resin mass after curing.  This configuration is particularly suitable for the manufacture of USB keys, in which case the maintenance of the support is advantageously achieved, at least in part, by means of a clamping element acting on a piece forming a USB interface, which does not need to be coated by any of the resin masses.  In fact, it is understood that the invention also allows the support and the wall that it runs in the first mold can be inclined, to which the free surface formed by the first mass of resin does not form a body face of the entity, nor a part of a slice perpendicular to a face of this body, but a surface inclined with respect to these faces; however, it should be noted that it is not a necessity that the body of a portable electronic entity has a parallelepipedal shape, and that its slices can be inclined without hindering the performance of this entity.  However, an inclined configuration can make it possible to cumulate the advantages of a horizontal configuration (the support rests on the contact wall, by its own weight, without requiring maintenance in position, in particular) and those of a vertical configuration (ease of operation). molding when an interface must overflow the two masses of resin, in particular).  It is thus understood that each of the horizontal and vertical configurations, or inclined, above is suitable for the manufacture of USB keys, especially given that the holders for USB keys are in principle rigid.  Indeed, in the case of a USB key, the support is typically a PCB (that is to say a printed circuit board (printed circuit board in English), epoxy); it conventionally carries metal interconnections between the components.  On the other hand, the manufacture of microcircuit cards is advantageously carried out in horizontal configuration only (or even inclined), given that these cards have a very small thickness, so that their manufacture in vertical configuration would involve casting the resin in a cavity formed of a very narrow slot, which could cause problems of distribution of the resin in this cavity, particularly because of air bubbles that could be trapped in the cavity, and therefore in the resin.  Preferably, especially when the support is rigid (and therefore has a significant thickness), at least one of the components is at least partly disposed in a depression formed in the support.  According to another advantageous variant, there is no interconnection between the components or, if there are interconnections, these are not carried by the support (they are elsewhere, carried out within the body or outside of it).  It must be understood here that the medium can be used for the manufacture of a single portable electronic entity (which has just been commented on) or, alternatively, for the manufacture of several adjacent electronic entities, in which case it is sufficient to provide then a separation of these adjacent entities.  To do this, either a global support is put in a large mold inside which a batch of adjacent entities is manufactured which is then separated from each other, or a support is used, of which successive parts are placed in the molds (preferably in two parts) to successively form entities from these support parts.  According to an advantageous variant, the holding in place of the support on the bottom or a side wall of the cavity of the first mold (and / or of the support and of the first mass of resin in the second open mold) is ensured, at least in part. , by means of suction holes.  Alternatively also advantageous, optionally combined with the previous one, the support is provided with an adhesive for its good maintenance on the bottom of the first mold open, which simplifies the structure of the molds.  The adhesive may be more effective than suction holes alone to prevent resin from creeping between the bottom of the mold and the face of the support facing it (eg provided with external contacts when the support carry a module) or plug the suction holes.  Alternatively, this adhesive is carried by the bottom of the mold in question, forming a wall of the cavity of this mold.  This feature is all the more interesting because, advantageously, the resin used for each of the first and second resin masses has a very low viscosity, preferably of the order of 60 MPa. s.  This very low viscosity has the particular advantage of facilitating the flow of the mass in the molds, as well as a good coating of the protruding parts, but also has the advantage of accelerating the formation of a flat and smooth free surface at the end of pouring when hardening begins.  However, in the case of more viscous resins, there may be smoothing by means of a tool.  The resins of the two masses may be identical, or if it brings an advantage, for example of color, different.  As already mentioned above, these resins can be molded so as to have equal thicknesses after curing.  In general, this resin (or these resins) have a viscosity of less than 10. 000 mPa. s, preferably less than 1000 mPa. and most preferably the most preferred value of 60 mPa above. $).  Each resin is preferably a polymerizable resin, preferably thermosetting, so that its hardening is controllable, at will, by heating.  This resin advantageously comprises a hardener, of any known type suitable.  This resin is, for example, polyurethane.  Preferably, the polymerizable resin is chosen so as to have, after the polymerization-curing step, a glass transition temperature greater than 50 ° C., preferably greater than 70 ° C.  Advantageously, each mold is heated after deposition and molding of the corresponding resin to initiate curing.  Preferably, the support comprises protrusions and / or depressions, or even holes, to promote the anchoring of the resin.  As indicated above, the components may optionally be disposed on the surface of the carrier or at least partially in depressions in the carrier.  Advantageously, the support also carries an antenna and / or a display, and / or a button, and / or a module provided with a microcircuit and external contacts, and / or a battery.  The invention further proposes, for the implementation of the aforementioned method, an open mold system whose cavity comprises a wall which comprises at least one depression so as to be able to go along a support of predetermined shape having a projecting portion of geometry 2903624 14 predetermined so that this projecting portion enters the depression and that the support along the wall away from this depression.  In a variant, this wall is compressible, or even, more generally, is adapted to the predetermined presence of protruding portions of the support.  Preferably, this open mold system comprises a heating device to be activated for a phase of curing a resin in this mold.  This mold, and said wall, is advantageously horizontally horizontal.  The invention also proposes a portable electronic entity obtained according to a particular case of the method of the invention, that is to say a portable electronic entity comprising a support between two molded resin masses, and at least one component carried by the support and coming flush or overflowing the free surface of one of the resin masses.  Description of the invention Objects, features and advantages of the invention will become apparent from the following description, given by way of non-limiting illustrative example, with reference to the accompanying drawings, in which: FIG. 1 is a sectional view of FIG. a support provided with components for the manufacture of a portable electronic entity, FIG. 2 is a view of this support placed in a mold according to an intermediate phase of the method of the invention, according to a first, generally horizontal configuration FIG. 3 is another view of this support placed in another mold in accordance with a subsequent phase of the process of the invention, FIG. 4 is a top view of a mold being put into operation. for manufacturing another portable electronic entity, FIG. 5 is a sectional view of still another mold being implemented for the manufacture of yet another portable electronic entity, and FIG. Figure 6 is a sectional view of yet another mold during implementation of the method of the invention, in a second configuration, generally vertical.  EXAMPLE OF EMBODIMENT FIGS. 1 to 3 show three states in the fabrication of a portable electronic entity, in a case where it is a microcircuit and display card (it appears in FIG. 3) and where a implements the method of the invention in a generally horizontal configuration.  The microcircuit and display cards are indeed a type of card capable of great development given the communication possibilities they allow with the holder of such a card.  However, it is recalled that the invention is generalized to the manufacture of a wide variety of portable electronic entities comprising various components, for example fragile mechanically or thermally (including, but not exclusively displays or batteries).  It is recalled that displays and batteries (or batteries) flexible are already available on the market.  However, these products are not compatible with the high lamination pressures (typically 20Kg / cm 2), nor with the temperatures (130-170 ° C) of hot lamination processes usually used by smart card manufacturers.  Methods of cold lamination or so-called warm lamination (70-90 ° C.) have been developed, but either the temperatures and / or the pressures used remain critical for the displays or the batteries, or said processes are expensive and not very industrial.  In addition, the lamination of this type of product requires the assembly of different sheets with windows or savings around the display and the battery (layers of protection, pressure compensation, concealment, etc.). ).  Portable electronic entities of the aforementioned type are therefore complex and expensive structures to implement by the technique of lamination.  Likewise, given the temperature and pressure conditions which are excessive for certain components, the manufacture of such portable electronic entities by injection molding also involves in practice complex and expensive operations, which may render this technique unrealistic in practice. .  FIGS. 1 to 3 describe how the implementation of the present invention makes it possible, in particular, to meet the objective of producing a display card without mechanical or thermal stress, thus allowing incorporation into the card body of systems Sensors such as displays, batteries, certain detectors or devices called MEMS (Micro Electrical Mechanical Systems).  In this case, the process uses polyurethane casting.  However, it should be understood that the invention is generalized to many other casting resins, preferably polymerizable, preferably of the thermosetting type, which allows to control the hardening.  In FIG. 1, a support 10 intended to come in a central position (in the direction of the thickness of the future card), of generally planar shape and having opposite faces 10A and 10B which are generally plane and parallel, is firstly prepared with at least one component.  This support has, together with this (or these) component (s) at least one projection.  In the example considered here, the components comprise a microcircuit 11 and a display 12 on the upper face 10A, a push button 13, a sensor 14 and other components or microcircuits jointly designated under the reference 15 on the underside 10B.  Alternatively, it may also include a battery, antenna, MEMS, piezoelectric button, flash memory, etc.  The various aforementioned components fixed and / or connected by techniques known per se (for example, wire solder, tin solder or flip-chip assembly for electronic components, bonding (can use anisotropic glues) for displays and detectors , photogravure for the antenna and the interconnecting tracks, etc. ).  The support is advantageously PVC, or PET, or epoxy glass, polyimide or another plastic material, rigid or flexible (this depends both on the constituent material and the thickness of this support).  It should be noted that these components may, if appropriate, be at least partly located in the thickness of the support.  In this case, the protruding portions formed on the surface of the support are formed by parts of components.  However, alternatively, it may be steps or extra thickness of this support.  Insofar as the card considered here is intended to have an external interface, the microcircuit 11 is here part of a module provided with external contacts 16 which, like the display, must be accessible from the outside. .  The support advantageously comprises the useful interconnections between at least some of the components.  In this respect, it should be noted that the various components can be connected on either side of the central sheet.  As shown in FIG. 2, this support 10 provided with the various components is then deposited on the bottom 21 of the cavity of an open mold 20.  Said bottom of the cavity has depressions (or spares) 22 and 23 which make it possible to house the components 11/16 and 12 which are connected on the upper face 10A of the support in FIG.  These cavities are thus arranged facing the protruding portions that the face 10A of the support when it is turned over and placed on the bottom of this cavity.  It may be noted that the module 11/16 occupies substantially the entire volume of the cavity 22 while the display 12 occupies only part of the height and section of the corresponding cavity 23.  It is within the abilities of those skilled in the art to define the appropriate geometry of the cavities according to the components to be preserved.  The support is advantageously plated on the bottom of the cavity by suction holes 25.  In variant not shown, this holding in position is achieved by means of an adhesive layer along the bottom of the cavity, possibly in combination with these suction holes.  The face 10B of the support is then covered, which in FIG. 1 was oriented downwards, but which is directed in this FIG. 2 upwards, by a casting of resin, preferably polyurethane (see the arrow down to FIG. FIG. 2).  The thickness of the resin mass thus deposited is such that the components 13 and 14 which must at least outcrop (come substantially at the outer surface of the body of the portable electronic entity, or even exceed or exceed the above this level) are surrounded but not covered.  It will be noted that the mold is horizontal and that the mass of resin 15 spreads spontaneously, if its viscosity allows it, to form a plane and smooth upper free surface (it will therefore not be necessary to polish it later).  The resin is then allowed to harden.  Preferably, if the resin is thermosetting, this curing is caused at the desired time, by heat input.  Advantageously, the mold comprises a heating device (shown diagrammatically at 28) for heating the wall, which promotes hardening.  We then return the half card 10 + 30 thus produced.  It is then positioned in the bottom 41 of the cavity of a second open mold 40 having here cavities (or savings) 42 and 43 corresponding to the components 13 and 14 located on the face 10B of the support and which it is desired that they are flush or overflowing, therefore accessible from the outside.  The upper face 10A of said support 10 (facing the open part of the mold) is then covered by a second resin casting (arrow in FIG. 3) so as to form a mass of resin 50 which has a surface 2903624 19 free superior which is flat and smooth; the resin is left (or in fact) subsequently cured.  Obviously, the thickness of the second cast is such that the components to be flush or protrude from the card body are not covered (this is the case of the display 12 and the external contacts 16 of the microprocessor module.  Like the mold 20, the mold 30 here has suction holes 45 but the maintenance can also be provided by a layer of adhesive along the bottom of the cavity of this mold.  The molds 20 and 30 are different here, but it should be understood that, if the geometry of the cavities allows it, especially when the bottom is lined by a layer of adhesive (which can thus temporarily seal cavities temporarily not used) it It is possible that both steps are performed in one and the same mold.  Several types of resin, such as epoxy resins, can be used in this process.  The preferred resins are polymeric resins, preferably polyurethanes of low viscosity or even very low viscosity (typically substantially equal to 60 mPa. s (or of the order of 50cps)) to obtain a very flat surface and reducing the risks of inclusion of air pockets between the components.  The resin is advantageously chosen so as to have a glass transition temperature greater than 50 ° C., preferably greater than 70 ° C.  The chosen resin cures at ambient temperature or at a very low temperature (typically 50 ° C.), which makes it possible to control the kinetics thereof by activating the heating device of the mold in question.  The masses 30 and 50 may be made of the same resin, or alternatively two resins having different characteristics, depending on the needs.  It will be appreciated that, provided the molds are arranged in a horizontal arrangement, such that the support is horizontal, the two faces of the final body, defined by the free surface of the resin masses before curing, are well parallel and smooth.  It will be appreciated that the method thus described thus makes it possible: to avoid any significant mechanical and thermal stress on the displays, batteries and any sensitive component, during the production of the card body; greatly reduce the costs of producing the plastic support by a simple and inexpensive method compared to multilayer hot lamination techniques; 10 - to remove the inserting operation of the microprocessor module by bonding said module on the previously machined central sheet.  Of course, it is not necessary that the surface of the support be identical in size to the surface of the bottom of the mold cavity (even if it helps to guarantee a good

  positioning of the support in the mold. It is even advantageous that the surface of said support is smaller than the bottom surface of the mold cavity to allow a total coating (including on the lateral edges of the support) of the central sheet (Fig.4). Thus, in FIG. 4, there is a support 10 'carrying a module 11' and a display 12 'on the upper face and other components 13', 14 'and 15' on the underside. , which rests on the bottom of a mold cavity whose surface is larger than that of this support, so that there remains a bottom portion 20B 'around this support. This allows better anchoring of the support in the resin as well as better protection of the components. Advantageously, the support comprises excrescences, and / or contrary to through depressions (holes) or not to also promote the connection between this support and the resin; such depressions or holes are represented under the reference 141 in FIG.

It should be noted that the present invention can not be limited to microcircuit cards.

For example, it is possible to integrate a display with a USB key by this method. On the other hand, if it has just been indicated that the support may have an area equal to or smaller than that of the bottom of the cavity of the molds, it is also possible for this support to be larger, for example by using a support which is formed of several elementary parts each intended to be part of a portable electronic entity. This is made possible by using a mold whose bottom and walls are separate pieces. Moreover, the formation of cavities in the bottom of a mold is not the only way to adapt the geometry of this bottom to the presence of protruding portions of the support placed on the bottom. Thus, FIG. represents a mold 70 having a bottom 70A and walls 70B and 70C which can be part of the same frame. On the bottom 70A, a support film 71 is placed, covered by a layer of compressible material 72, here an adhesive layer, in which protruding parts 81 and 82 of the support 80 can be printed, for example consisting of projecting component parts. Before or after placing the support 80, the mold walls 70B and 70C are brought closer to each other and towards the bottom so as to delimit a mold cavity. There is then only to pour the mass of resin to be molded. It may be noted that the layer 72 here forms the bottom of the mold cavity, which is therefore distinct from the bottom of the mold itself. The bottom 70A is here represented with suction holes; these can be used to press the support film against the bottom of the mold (or its cavity), but it is understood that these can also be used to hold the support itself in position, particularly if this film is replaced by other means of adaptation to the presence of parts projecting downwards, which do not cover the entire bottom 70A. We observe the presence, under the left wall 70C, an insert part 90 for forming a USB interface (or USB connector) for enabling the connection of the future portable electronic entity to a USB port of a microcomputer or similar device; in practice, the second mold 2903624 22 then also has movable walls to allow the presence of such a USB interface; it should however be noted that the implementation of the USB interface can also intervene only during the casting of the second mass of resin, in which case only the second mold needs to have at least one movable wall; It is understood that thus the invention allows the manufacture of a USB key. A seal such as that shown under the reference 95 is advantageously provided near the interface between this insert 90 and the left wall of mold 70C. It may be noted that in Figure 5, a component 83 is shown which is not connected to the carrier. It is thus understood that the geometry of the support can be chosen according to the needs and can therefore be much smaller than the cavity of the molds. The invention can also be implemented by using a large support which, like the layers 71 and 72, is interposed between a bottom and mold walls.

The examples considered above correspond to a generally horizontal configuration of the support during the production of the resin masses. Figure 6 corresponds to another configuration, generally vertical, in which the support 110, preferably rigid (for example a support commonly called PCB) runs along a side wall 121 of the cavity of a mold 120 deeper than wide. This wall 121 is, as in Figure 5, formed of a layer of compressible material 172 along the underlying wall of the mold. This mold has a wall 121B which is opposite and whose geometry determines the face of the future mass of resin which will extend substantially parallel to the support. This wall 121B is in practice parallel to the wall 121. This support 110 comprises, as previously, protruding components, designated under the references 112, 113, 114 and 115. It may be noted in this respect that the component 115 is in position. part disposed in a depression 30 formed in this support that is to say that it is partly located in the thickness of this support.

2903624 23 This support is provided with protuberances (and therefore projecting parts) and / or depressions, or even through holes, denoted 141, which facilitate the anchoring of the support to the resin; there may be on both sides of the support.

The carrier here contacts the bottom of the mold cavity. Furthermore, this support is held in position by a clamp 200, here mounted by the mold itself. Preferably, this support 110 is intended for the manufacture of a USB key and comprises, at its upper part, an element 190 forming a USB interface. Taking advantage of the fact that this interface is not intended to be coated by the resin masses, this element is advantageously used for the mechanical support of the support by the clamp 200. After pouring the mass of resin through the nozzle and curing of this, optionally by heating mold walls, by means of heating elements schematized under the reference 300, as indicated with reference to the preceding figures, the assembly of the support and the first mass of resin is placed in a another open mold, horizontal or vertical, for the formation of the second mass of resin. In a variant, the support is only held in position by the clamp, without coming into contact with the bottom of the mold, or with the side walls situated in front of and behind the cutting plane of FIG. 6. It will be appreciated that the The invention makes it possible to control the thickness of the various resin masses.

Claims (49)

  1. A method of manufacturing a portable electronic entity comprising a support and at least one component, this method comprising the following steps: - preparation of a support provided with a component and having first and second generally planar and parallel opposed faces locating said support in the open cavity of a first open mold in a configuration in which this support runs along its first face a wall of this open cavity, casting without pressure in this cavity of the first open mold of a first mass of resin along the second face of the support, then hardening of this first mass of resin so as to secure it to this second face, - placement of this support, with the first mass of resin, in the open cavity of a second open mold in a configuration in which this first mass of resin runs along a wall of the cavity of this second mold open, casting without pressure of a second m sse resin along the first side of the support and hardening of the second mass of resin so as to secure it to this first face.   2. Method according to claim 1, characterized in that said support comprises, with the component, a protruding portion vis-à-vis the first face of the support, said wall of the cavity of the first open mold against which this face comes into contact being shaped so as to have a depression opposite this protruding part when the support is in contact with this first face with said wall of the cavity of this first open mold, whereby the contact of the support with said wall of the cavity of this first open mold is essentially made at a distance from this projecting portion.   3. Method according to claim 1 or claim 2, characterized in that the support comprises, with the component, a protruding portion vis-à-vis the first face of the support, said cavity wall of the first 2903624 25 open mold with which this face comes into contact being compressible so as to adapt to this projecting portion.   4. Method according to claim 1, characterized in that, the support having, with the component, at least one protruding part, said wall of the cavity of the first mold comprises means of adaptation to the presence of this part. protrusion so as to allow the support is parallel to this wall and flat.   5. Method according to any one of claims 2 to 4, characterized in that the projecting portion is part of the support. 10   6. Method according to any one of claims 2 to 5, characterized in that the protruding part is part of the component.   7. Method according to any one of claims 2 to 6, characterized in that the support comprises at least one other projecting portion located on its second face. 15   8. Process according to any one of claims 1 to 7, characterized in that: the support is placed in the first open mold in a configuration in which it is substantially horizontal, said wall of the first open mold lined by this support being the bottom of the cavity of this first open mold, and the first mass of resin is poured without pressure into this cavity of the first open mold so as to form by this first mass of resin a first horizontal free surface, the support is returned after curing the first resin mass and then placed in the second open mold in a configuration in which it is substantially horizontal, said wall of the second open mold lined by the first mass of resin being the bottom of the cavity of the second open mold , and the second mass of resin is poured without pressure into this cavity of the second open mold so as to form by this second of resin mass a second horizontal free surface. 30   9. The method of claim 8, characterized in that the support comprises, with the component, a protruding portion vis-à-vis the first face 2903624 26 of the support, which comes flush or overflowing the free surface of the second resin mass.   10. A method according to claim 8 or claim 9, characterized in that the support comprises at least one other protruding portion 5 vis-à-vis the second face of the support, which comes flush or overflows the free surface of the first mass of resin.   11. The method of claim 10, characterized in that the bottom of the cavity of the second open mold is shaped so as to have a depression opposite this other portion flush or overflow, when the support is placed by the first mass of resin on the bottom of the cavity of the second open mold.   12. The method of claim 10 or claim 11 characterized in that the bottom of the cavity of the second open mold is shaped so as to be compressible opposite this other portion flush or overflow when the support is placed by the first mass of resin on the bottom of the cavity of the second open mold.   13. Method according to any one of claims 10 to 12, characterized in that the bottom of the cavity of the second open mold comprises means of adaptation to the presence of components flush with or exceeding the surface of the first mass of resin.   14. The method of claim 3 or claim 12, characterized in that the compressible material is an adhesive layer.   15. The method of claim 14, characterized in that the compressible material is carried by a support film along the bottom of the open mold 25 which this compressible material forms the bottom of the cavity.   16. A method according to any one of claims 8 to 15, characterized in that the support has, horizontally, a shape substantially equal to that of the bottom of the first open mold.   17. Method according to any one of claims 8 to 15, characterized in that the support has, horizontally, a shape smaller than that of the bottom of the first open mold. 2903624 27   18. Method according to any one of claims 8 to 17, characterized in that the portable electronic entity is a microcircuit card and the support is a central inlay.   19. A method according to claim 18, characterized in that the inlay has a thickness of between 0.04 mm and 0.25 mm, and the two resin masses between which this inlay is disposed each have a thickness of between 0.1 mm and 0.38 mm. .   20. The method of claim 18 or claim 19, characterized in that the two resin masses between which this inlay is disposed have equal respective thicknesses.   21. Method according to any one of claims 18 to 20, characterized in that the support carries a module provided with a microcircuit and external contacts.   22. Method according to any one of claims 18 to 21, characterized in that the support is flexible.   23. Method according to any one of claims 8 to 17, characterized in that at least one of the molds comprises at least one movable side wall for interposing a USB interface between the movable side wall and the bottom of the cavity of this mold during casting of the resin mass.   24. Method according to any one of claims 1 to 7, characterized in that the wall of the cavity of the first open mold is a vertical side wall against which the support is maintained in a configuration in which it is vertical. 25   25. The method of claim 24, characterized in that the support comprises a USB interface by which the support is maintained in the open mold, said portable electronic entity being a USB key.   26. Method according to any one of claims 1 to 17 and 23 to 25, characterized in that the support is rigid. 30   27. The method of claim 26, characterized in that the portable electronic entity is a USB key. 2903624 28   28. A method according to any one of claims 1 to 27, characterized in that the component is at least partly disposed in a cavity in the support.   29. Method according to any one of claims 1 to 28, characterized in that the support is used for the manufacture of several adjacent portable electronic entities which are then separated.   30. Method according to any one of claims 1 to 29, characterized in that the holding in place of the support on the bottom of at least one of the open molds is provided by means of suction holes. 10   31. Method according to any one of claims 1 to 30, characterized in that the holding in place of the support on the bottom of one of the open molds is provided by means of an adhesive.   32. Process according to any one of claims 1 to 31, characterized in that the two resin masses have equal respective thicknesses.   33. Process according to any one of claims 1 to 32, characterized in that this viscosity is less than 1000 mPa.s.   34. The method of claim 33, characterized in that this viscosity is substantially equal to 60 mPa.s. 20   35. Method according to any one of claims 1 to 34, characterized in that the glass transition temperature is greater than 70 C.   36. Process according to any one of claims 1 to 35, characterized in that the first and second resin masses are of identical resins.   37. Process according to any one of claims 1 to 36, characterized in that the resin comprises a hardener.   38. Process according to any one of claims 1 to 37, characterized in that the resin is polymerizable. 30   39. Process according to any one of claims 1 to 38, characterized in that the resin is a thermosetting resin. 2903624 29   40. The method of claim 39, characterized in that the mold is heated after deposition and casting of the resin to trigger its hardening.   41. A method according to any one of claims 1 to 40, characterized in that the support comprises excrescences or cavities for anchoring the resin.   42. Method according to any one of claims 1 to 41, characterized in that the support carries a battery.   43. Process according to any one of claims 1 to 42, characterized in that the support carries an antenna.   44. Process according to any one of claims 1 to 43, characterized in that the support carries a display.   45. "A method according to any one of claims 1 to 44, characterized in that the support carries a button.   46. An open mold system, comprising an open mold whose cavity comprises a wall which comprises at least one depression so as to be able to go along a support of predetermined shape having a protruding portion of predetermined geometry so that this protruding part penetrates into this depression and the support runs along this wall at a distance from this depression.   47. Open mold system according to claim 46, characterized in that this mold comprises a heating device for curing a resin in this mold.   48. System according to claim 46 or claim 47, characterized in that the wall is generally horizontal.   49. Portable electronic entity comprising a support between two masses of molded resin, and at least one component carried by the support and coming flush or overflow of the free surface of one of the resin masses. 30