FR2817656A1 - ELECTRICAL INSULATION OF GROUPED MICROCIRCUITS BEFORE UNIT BONDING - Google Patents

Abstract

The invention concerns electrical insulation of assembled chips (2), before being bonded into a single unit (9, 13). It comprises steps which consist in: applying a protective dielectric layer on at least an active surface (6) of a chip (3) of the wafer; placing then fixing on its substrate (8) the chip (3), by bonding its rear surface, a periphery of the protective layer (14) forming a barrier (15); and connecting after protecting, at least a contact pad (10) to the corresponding pad (7). The invention is useful for making portable smart objects, such as chip cards or labels.

Description

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 The invention relates to the general field of manufacturing electronic devices comprising at least one microcircuit fixed on a support and protected by an insulator. Such a device is called a module.

In this field, the microcircuit technique fixed on a support is called in English die attach.

 The invention applies to modules intended for or integrated into intelligent portable objects, in particular smart cards and electronic labels.

To situate the invention, let us quickly describe such a microcircuit:
The microcircuit is made of a semiconductor material called a substrate: it is for example silicon. A microcircuit has two opposite main faces, one called the active face covered by a passivation layer, with the exception of connection pads. The other side is called rear or bulk in English. Between these two faces is a peripheral edge.

 In a module, the microcircuit is mounted either with its passive face against the support and the connection pads of the active face opening out opposite the support. Either the active face is opposite the support. We then speak in English of flip chip: this assembly is not concerned here.

 In an assembly as in the other, the peripheral edge and the rear face are conductive, and they should be electrically isolated after sawing making the microcircuit unitary.

 In addition, this microcircuit - and more broadly the module - must be provided with protection against external damage in particular, physicochemical like humidity, and mechanical like shock or stress.

 This electrical and mechanical protection is carried out differently depending on the type of connection of the pads with interface elements of the module. Here these elements are indifferently electrically connected to (or form part of a terminal block with contact pads such as that of a bank chip card, and / or to a contactless transmission antenna, such as in an electronic label.

 A known type of connection to interface elements is called wired wiring. The document FR-A-2684802 describes a wired wiring, where the pads of the microcircuit are connected to interface elements by metallic wires.

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 In general these wires are made of gold, copper, nickel or a metal alloy which makes the connection expensive. While laying these wires requires precision equipment which slows down the production rate. In addition, it is understood that a wired connection is a delicate operation, since it is necessary to position and then weld in place wires of microscopic section and length.

 With wired wiring, it is common to cover the microcircuit fixed on the support and its connections, with a drop of insulating material. In English, this covering is called glob top. It consequently increases the thickness (that is to say the distance between the rear of the support and the top of the protection, measured transversely to the faces of the microcircuit) and the rigidity of the module thus obtained.

 Another type of connection of the pads of a microcircuit to the interface elements uses, instead of the soldered wires, electrically conductive polymer compounds. The document FR-A-2761498 describes this type of connection, where the pads and the interface elements are connected by depositing a resin such as a polymerizable adhesive charged with conductive particles, for example silver.

 These connections by known polymer deposition are economical and efficient.

 However, in practice there are drawbacks linked in particular to the insulation of the wafers of the microcircuit which have an electrical conductivity, for example of the order of 0.01 ohm / mm (all the more important as the substrate is doped to increase its electronic properties).

 Because of this insulation problem, another type of connection is chosen.

 Either it is attempted that the adhesive for fixing the microcircuit on its support is deposited so that it extends opposite the peripheral edges to ensure protection.

 However, it is difficult in manufacturing to obtain that the protection has an appropriate thickness (that is to say the distance between the support and the top of the protection, measured transversely to the faces of the microcircuit). Because either only part of the thickness of the microcircuit is covered by the adhesive: there is then on the edge, a peripheral zone without insulating protection, near the active face.

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 Either the drop of glue in which the microcircuit is fixed overflows on its active face, or even the connection pads, which is not acceptable.

 This comes from the fact that the dimensional constraints imposed are difficult to meet with current equipment. The target dimension for the glue thickness is for example of the order of 80% of the thickness of the microcircuit (for example 180 μm) with a tolerance of the order of +/- 10% of the thickness of the microcircuit .

 In addition, in many cases, it is desirable to obtain the smallest possible thickness of the module (for example to comply with requirements such as the standard IS07816 on smart cards), that is to say the distance between the outside of the support and the protection, measured transversely to the faces of the microcircuit.

 While it is often desired that the module has flexibility properties in correspondence with those imposed on the portable object (card, label or the like) for which it is intended.

 The invention aims to overcome these drawbacks in particular.

 It aims to ensure that the conductive areas of the microcircuit, and in particular its peripheral edges, are fully protected. Of course, the term entirely excludes the parts of the microcircuit which it is necessary to be able to access, such as for example the connection pads. Apart from these zones, it is desired to achieve protection extended over substantially 100% of the conductive surface of the microcircuit.

 In addition, the invention must allow the integration of the microcircuit protection steps in an online and continuous manufacturing. The rate of the protection steps must therefore be close to that of the upstream and downstream steps, depending on the direction of the micromodule manufacturing process. This is not the case for example for wired cabling.

 To this end, an object of the invention relates to a method of manufacturing an electronic device, in particular an intelligent portable object module such as a smart card or electronic label.

 This method includes the steps of: mounting on a sawing vehicle a so-called wafer semiconductor plate, forming a substrate for several microcircuits; saw each of the microcircuits to make them unitary; place and then fix the microcircuit on its support;

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 connect at least one interface element to at least one corresponding pad; and deposit the protective material.

 According to the invention, the method comprises the steps providing: 'before the substrate plate is sawn, applying a protective dielectric layer on at least one active microcircuit face of this plate; at least one access recess being reserved or formed in this dielectric layer, which opens facing at least one connection pad; '' for at least one micromodule, to place it then to fix it on its support, by gluing of its passive face, a periphery of the protective layer forming for example barrier against the overflow of the glue on the active face of the microcircuit; and 'connect after protection, each interface element to the corresponding pad, for example by depositing conductive material.

 According to one characteristic, the step during which the protective layer is applied is carried out before the mounting of the so-called wafer plate on its sawing vehicle.

 According to another characteristic, at least one microcircuit having on the active face a passivation layer; the protective layer is applied to this passivation layer.

 According to yet another characteristic, the steps providing for applying the protective layer, for placing then fixing the microcircuit on its support and for connecting it, are integrated into an online and continuous manufacturing process, the rate of these steps being close to that of manufacturing stages upstream and downstream, according to the direction of the process.

 In one embodiment, the protective layer is a dielectric polymer film, of a thickness for example of the order of 50 μm, applied by lamination and through which at least one access cavity reserved prior to lamination; this obviously opening facing at least one connection pad and being formed by laser cutting, mechanical such as stamping or the like.

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One embodiment provides that the protective layer is a dielectric polymer film, of a thickness for example of the order of 50 μm, applied by lamination and through which at least one access recess is formed after lamination on the active face. ; this obviously opening facing at least one connection pad and being formed by laser cutting, mechanical such as stamping or the like.

 In another embodiment, the protective layer is a polymeric and initially viscous dielectric material, applied by screen printing; at least one access opening is formed using a screen comprising at least one masking area avoiding depositing the screen printing material opposite at least one connection pad.

 Yet another embodiment provides that the protective layer is a polymeric and initially viscous dielectric material, such as ink or polymer adhesive, applied jet for example from a matrix of nozzles with a section of the order of 20 μm for example; at least one access recess is formed by programming during the projection of the jets through this material, this obviously opening facing at least one connection pad.

 An implementation with the application of an initially viscous material by screen printing or ink jet provides, for example before sawing making the microcircuits of a unitary substrate plate, a step of polymerization by thermal, photonic, chemical contribution or the like.

 According to one characteristic, the protective layer forms a barrier for example with a thickness of 70 μm and having a substantially identical external profile as well as at the right of the peripheral edge, against the overflow of the adhesive towards the inside on the active face. of the microcircuit, during the fixing step.

 In one embodiment, the microcircuit is fixed to the support by placing in a deposit of insulating polymer adhesive such as a resin; this adhesive rising during placement against the external peripheral edge of the microcircuit; for example, the thickness of glue is between 80% and 100% of the thickness of the microcircuit such as of the order of 180 μm, with a tolerance of the order of +/- 10% of the thickness of the microcircuit.

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One characteristic provides that the step aimed at connecting, after protection, each interface element to the corresponding pad, is carried out by depositing conductive material such as resin or polymer adhesive charged with electrically conductive particles or intrinsically conductive polymer, for example by pad printing, jet ink, syringe removal or the like.

 In one embodiment, the connection material is deposited on the fixing adhesive and on at least one external part of the protective dielectric layer applied to the substrate, for example by covering a peripheral barrier with this layer, while possibly a part of the active face and / or of its passivation layer is devoid of this protective and / or covering layer by the connection material.

 In one embodiment, a connection input called boss or "bump" is deposited after fixing the microcircuit on its support, for example prior to the step providing for connecting the pad to the corresponding interface element; this contribution being disposed on this pad and intended to receive an electrical connection end portion of the interface element.

Another object of the invention relates to an electronic device forming an intelligent portable object module such as a smart card or electronic label.

This device comprises, once manufactured, at least: 'a microcircuit provided with at least:' a peripheral wafer which has a conductivity 'on either side of the wafer, two main faces, one rear and the another active because provided with at least one connection pad 'a dielectric support, on which is fixed the passive face of the microcircuit, by gluing. an interface element electrically connected to the pad by a conductive material called interface 'a protection structure of the micromodule made of electrically insulating material called protection.

 According to the invention, the protective structure is applied to at most part of the active face of the microcircuit, close to or in contact

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 with the fixing adhesive, for example via a peripheral barrier of this structure; this structure being at least partly covered by the conductive interface material ensuring the connection.

In one embodiment, at least one insulating part of the active face of the microcircuit, for example part of its passivation layer, is free, that is to say devoid of any protective layer and / or connection material
A feature provides that this device is manufactured according to the process mentioned above.

 Yet another object of the invention relates to equipment such as an online and continuous production line for an electronic device, forming an intelligent portable object module such as a smart card or electronic label.

 This equipment has a unit for depositing an insulating protective layer on a plate grouping together several microcircuits, upstream of a station for mounting the plate on a sawing vehicle; while downstream of a fixing station by bonding a unitary microcircuit on a support, the equipment has a station for depositing a conductive connection material.

 It is suitable for implementing the method and / or for manufacturing the electronic device forming module mentioned above.

 Now, the invention will be described with reference to non-limiting examples of implementation, and illustrated in the accompanying drawings.

 In these drawings, FIG. 1 represents in partial schematic section, on the one hand (top) a solid protective layer to be laminated, and on the other hand (bottom) a plate forming a substrate for microcircuits.

 FIG. 2 is a view similar to FIG. 1, which represents on the one hand (top) a solid protective layer provided with access recesses, and on the other hand (bottom) a plate forming a substrate for microcircuits, its connection pads being opposite the recesses.

 FIG. 3 shows in partial schematic section, a manufacturing step during which access recesses are formed in a solid protective layer laminated on a plate forming a substrate for microcircuits.

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 FIG. 4 shows in partial schematic section, a manufacturing step during which a layer of viscous protective material is deposited by screen printing or ink jet, on a plate forming a substrate for microcircuits, access recesses being formed during the deposit in this layer.

 FIG. 5 is a view similar to the previous ones, which illustrates a step of mounting a substrate plate for microcircuits on its sawing vehicle.

 FIG. 6 is a view similar to FIG. 5, which illustrates the result of a step of sawing a substrate plate into microcircuits, the latter remaining on the vehicle.

 FIG. 7 represents in schematic section, the result of a step of fixing a microcircuit on its support, using a polymer adhesive.

 FIG. 8 represents in schematic section, the result of a step of connection of the pads of a microcircuit on its support, by deposition of a polymeric material on the fixing glue and a protective layer, in particular.

application d'une couche de protection 'montage de substrat sur véhicule de sciage 'sciage des microcircuits fixation de microcircuit sur son support . connexion des plots à des éléments d'interface, et 'intégration du module dans un objet portable intelligent, ici par encartage . And FIG. 9 schematically represents an equipment for manufacturing modules and portable objects (here a smart card), with, depending on the direction of the process implemented by the equipment, stations for:

application of a protective layer 'mounting of substrate on sawing vehicle' sawing of microcircuits fixing of microcircuit on its support. connection of the pads to interface elements, and 'integration of the module into an intelligent portable object, here by inserting.

 In FIG. 8 in particular, an electronic device 1 can be seen. This device 1 forms a module also designated in 1, for an intelligent portable object 2 such as the smart card shown in FIG. 9.

 It appears from this FIG. 8 that the device 1 comprises: a microcircuit 3 provided with at least: 'a peripheral section 4 which has a conductivity

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on either side of the wafer, two main faces (5,
6), one designated at 5 called rear and the other designated at
6 called active, because it is provided with pads 7 for connecting a dielectric support 8, on which the passive face 5 of the microcircuit 3 is fixed, by bonding using a fixing material 9 of the interface elements 10, electrically connected to the pads
7 by a conductive material called interface 11. a micromodule protection structure, generally designated at 12 in FIG. 8 and comprising in particular a first electrically insulating material 13. More generally, all the materials of the structure 12 are called thereafter protective materials.

 In FIG. 8, the structure 12 comprises two protective materials, namely on the one hand the first material 13 which is in fact the fixing glue mentioned above.

 On the other hand, the structure 12 according to the invention comprises a second protective material 14. This same reference numeral 14 also designates a component of the structure 12 called the protective layer.

 It appears from FIG. 8 that the second material 14 is applied before sawing (on the plate or wafer), but only on part of the active face 6, in contact with the adhesive 9 also acting as the first protective material 13.

 More specifically, here is a peripheral barrier 15 of the layer 14 (in particular visible in FIG. 7), which is in contact with the fixing and protection adhesive designated at 9 and 13 according to its function.

 This distinguishes the protective structure of the invention from known connections by deposition with a syringe (in English exemption) of conductive polymer, where an insulation material is deposited during a dedicated step subsequent to the fixing of the microcircuit on its support. , against the edge to be insulated.

 It should also be emphasized that here the structure 12 is partly covered by the conductive interface material 11 ensuring the connection. In glob top protection in particular, the interface conductor is covered by the drop of resin.

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In the embodiment of FIG. 8, an insulating part 16 of the active face 3, here of its passivation layer, is cleared, that is to say devoid of any protective layer and / or connection material
Let us now describe how this device 1 is manufactured and on which equipment such as that designated in 17 (which schematizes here an online and continuous production line for electronic devices) and visible in FIG. 9, is implemented) the method of the invention.

'poste d'application 19 d'une couche de protection 14 'poste de montage 20 de substrat sur un véhicule de sciage (désigné en 25 sur les figures 5, 6 et 9) 'poste de sciage 21 des microcircuits 3 'poste de fixation 22 de microcircuit sur son support 8 'poste de connexion 23 des plots 7 aux éléments d'interface 10, et 'poste de intégration 24 du module (1) dans un objet portable intelligent, ici la carte 2. According to a direction of flow of the process designated at 18 in FIG. 9, the equipment 17 comprises one (or more):

'application station 19 with a protective layer 14' mounting station 20 for substrate on a sawing vehicle (designated 25 in FIGS. 5, 6 and 9) 'sawing station 21 for microcircuits 3' fixing station 22 of microcircuit on its support 8 'connection station 23 of the pads 7 to the interface elements 10, and' integration station 24 of the module (1) in an intelligent portable object, here the card 2.

 To simplify reading, the steps performed on these stations are designated by the same reference numerals.

 This equipment 17 has its station 19 for unitary application of the insulating protective layer 14 on a plate or substrate designated at 26 and grouping together several microcircuits, upstream from the mounting station 20, according to the direction 18 of the process.

 While downstream of the fixing station 22 (here by bonding), the equipment 17 has a station 23 for depositing a conductive material 11 ensuring the connection of the microcircuit 3 to the interface elements (here a terminal block for a card smart).

 Referring to FIGS. 1 to 8 in particular, let us pass to the description of the process for manufacturing electronic devices 1.

 Conventionally, such a method comprises the following chronological sequence of steps providing for: mounting (as illustrated by the arrow 20 in FIG. 5), on a sawing vehicle 25 a semiconductor plate called a wafer 26, forming a substrate unit for several microcircuits 3;

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'scier (comme illustré par la flèche 21 sur la figure 6) par exemple à l'aide d'un outil diamanté tel que scie circulaire, chacun des microcircuits 3 pour les rendre unitaires, mais en les gardant solidaires et soutenus par le véhicule 25 ; 'placer puis fixer (sur un poste tel que celui désigné en 22 sur la figure 9) le microcircuit 3 sur son support 8 ; 'connecter (sur un poste tel que celui désigné en 23 sur la figure
9) les éléments d'interface 10 aux plots 7 correspondants ; puis . déposer le matériau de protection.

'' saw (as illustrated by arrow 21 in Figure 6) for example using a diamond tool such as circular saw, each of the microcircuits 3 to make them unitary, but keeping them integral and supported by the vehicle 25 ; 'place then fix (on a station such as that designated at 22 in Figure 9) the microcircuit 3 on its support 8; '' connect (on a station such as that designated at 23 in the figure
9) the interface elements 10 to the corresponding pads 7; then. remove the protective material.

According to the invention, the manufacturing process comprises in synthesis, according to the direction of unfolding 18, the stages providing: before the plate 26 forming the substrate is sawn (at 21), applying (in step 19 in FIG. 9) a dielectric layer
14 of protection on at least one active face 6 of microcircuit
3 of this plate 26; '' for at least one micromodule 3, place it and then fix it (in step 22 in Figure 9) on its support 8, by bonding its passive face 5, a periphery of the layer 14 forming the barrier 15 against the glue overflow (9-13) on the active face 6 of the microcircuit 3; and connect as illustrated at 23 in FIG. 8, after having finalized the protection as illustrated in FIG. 7, each interface element 10 to the corresponding pad 7, here by depositing (step 23) of conductive material.

 We have therefore seen that step 19 during which the protective layer 14 is applied, is carried out before mounting the plate 26 on its vehicle 25. In the examples, note that the microcircuits 3 have on their active face 6 a passivation layer which is not shown: the protective layer 14 is applied to this passivation layer.

 Other features of the process are now described.

 In the examples, the steps providing for applying at 19 the protective layer 14, placing then fixing at 22 the microcircuit 3 on its support 8 and connecting it (23), are integrated into a continuous and online manufacturing process . The pace of these stages is close to

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 that of manufacturing stages upstream and downstream, according to the direction of flow 18 of the process.

 In FIGS. 1 to 3 and 9, the protective layer 14 is a dielectric polymer film, with a thickness for example of the order of 50 μm. This film is first unwound from a distribution reel 29 and then applied by lamination.

 FIG. 2 shows such a film, also designated at 14, through which access recesses 30 are reserved prior to lamination.

Each obviously 30 opens once the layer 14 applied to the plate 26 as illustrated in FIG. 4, opposite the connection pads 7. On the film 14, the recesses 30 are previously formed by laser cutting, mechanical cutting or stamping or similar, before re-reeling 29.

 The embodiment of FIG. 3 shows a protective layer 14 of polymeric dielectric film, also applied by lamination. But here, the access recesses 30 are formed after lamination on the active face 6.

 A cutting tool is designated at 31 to form these recesses 30. According to the embodiments, this tool operates the cutting in the film 14 by laser, stamping or the like.

 In the embodiment of FIG. 4, the protective layer 14 is a polymeric and initially viscous dielectric material. Here, layer 14 is applied by screen printing. Then, the recesses 30 are formed during screen printing, so that there is no protection at the desired locations.

 More precisely, a screen with a masking area is used to prevent the deposition of screen printing material on the pads 7.

This screen is not shown in the figures.

 Yet another embodiment provides that the protective layer 14 is also made of a polymeric and initially viscous dielectric material, such as ink or polymer adhesive, but is here applied by jet of material. For example, a matrix of nozzles with a section of the order of 20 μm launches material 14 on the face 6, except at the location of the recesses 30. This is obtained by programming when the jets are projected.

 The result achieved at the end of the application step, whatever the technique, is such as that shown in FIG. 4: the face intended for

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former les faces actives 6 de la plaque 26 est"entièrement"revêtue de) a couche 14, sauf à l'emplacement des évidements 30.

forming the active faces 6 of the plate 26 is "entirely" coated with) a layer 14, except at the location of the recesses 30.

 An implementation with the application of an initially viscous material by screen printing or ink jet provides, for example before sawing 28, a step of polymerization by thermal, photonic, chemical or the like. This step is shown diagrammatically in FIG. 4 at 32.

 It appears from FIGS. 7 and 8 in particular that the layer 14 has a barrier 15 (in this embodiment with a thickness of 70 μm) whose external profile is substantially identical to — as well as to the right of — the peripheral section 4. The barrier 15 prevents the glue 9/13 from overflowing inwards onto the active face 6. In fact, the glue 9/13 creeps upwards and against the slabs 4, during the step of fixing the microcircuit 3. Here , this glue 9/13 is an insulating polymer resin.

 At the end of the fixing, this adhesive 9/13 is raised against the external peripheral edge 4 of the microcircuit 3.

 In one embodiment, the thickness of glue 9/13 is between 80% and 100% of the thickness of the microcircuit 3 such as of the order of 180 μm, with a tolerance of the order of +/- 10% of the thickness of the microcircuit 3.

 Referring to Figure 8, it is understood that step 23 aimed at connecting the pads 7, is carried out by depositing conductive material 11 such as resin or polymer adhesive. Such an adhesive is either intrinsically electrically conductive, or it is charged with electrically conductive particles.

 According to the embodiments, this connection is made by pad printing, ink jet, syringe deposition or the like.

 It appears from FIG. 8 that here the connection material 11 is deposited on the fixing adhesive 9/13 and therefore on an external part of the dielectric protective layer 14.

 The peripheral barrier 15 is here locally covered by the connection inputs 11.

 It can also be seen that the part 16 of the active face 6 and therefore of the passivation layer, is devoid of this protective layer 14.

 In an embodiment not shown, a connection contribution called boss (or "bump" in English) is deposited after fixing the microcircuit 3 on its support 8. This contribution is often placed on the

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 studs 7 and intended to receive an end portion of the electrical connections 11 to the interface elements 10.

 The invention also covers intelligent portable objects 2 such as the card in FIG. 9. But other objects 2 also fall within its scope, such as electronic tags or other objects communicating without contact.

 Thus, flexible electronic labels are a possible application of the invention. Indeed, it is easier because of the absence of glob top for example, that the module has flexibility properties in correspondence with those imposed.

 Thanks to the invention, the dimensional constraints imposed are easier to comply with, in particular due to the barrier 15. It is thus possible to easily obtain the smallest possible thickness of the module.

 Finally, the invention allows the integration of the microcircuit protection steps in an online and continuous manufacturing, at a rate close to that of the upstream and downstream steps. It provides optimal protection for the microcircuit, with bonding and exemption connection techniques.

Claims (20)

 CLAIMS 1. Method for manufacturing an electronic device (1), in particular an intelligent portable object module (2) such as a smart card or electronic label; This method includes the steps of: mounting (20) on a sawing vehicle (25) a semiconductor plate (26) called a wafer, forming a substrate for several microcircuits (3); sawing (21) each of the microcircuits to make them unitary (3); place then fix (22) the microcircuit (3) on its support (8); connecting (23) at least one interface element (10) to at least one corresponding pad (7); and deposit the protective material.  According to the invention, the method comprises the steps providing: before the substrate plate (26) is sawn, to apply (19) a dielectric protective layer (14) on at least one active face (6) of microcircuit (3) of this plate; at least one access recess (30) being reserved or formed in this dielectric layer (14), which opens facing at least one connection pad (7); for at least one microcircuit (3), to place it then to fix it (22) on its support (8), by bonding of its passive face (5), a periphery of the protective layer (14) forming for example a barrier (15) against the overflow of the adhesive (9) on the active face (6) of the microcircuit (3); and connect (23) after protection (19,22), at least one interface element (10) to the corresponding pad (7), for example by depositing conductive material (11). 2. Method according to claim 1, characterized in that the step (19) during which the protective layer (14) is applied, is carried out before mounting (20) of the plate (26) called wafer on its vehicle sawing (25). <Desc / Clms Page number 16> 3. Method according to claim 1 or 2, characterized in that for at least one microcircuit (3) having on its active face (6) a passivation layer, the protective layer (14) is applied to this passivation layer. 4. Method according to one of claims 1 to 3, characterized in that the steps providing for applying (19) the protective layer (14), placing and then fixing (22) the microcircuit (3) on its support ( 8) and to connect it (23), are integrated into an online and continuous manufacturing process, the rate of these steps being close to that of upstream and downstream manufacturing steps (24), in the direction (18 ) of the process. 5. Method according to one of claims 1 to 4, characterized in that the protective layer (14) is a dielectric polymer film, of a thickness for example of the order of 50 µm, applied by lamination (19) and through which at least one access recess (30) reserved prior to the lamination; this obviously opening facing at least one connection pad (7) and being formed by cutting (31) laser, mechanical such as stamping or the like. 6. Method according to one of claims 1 to 5, characterized in that the protective layer (14) is a dielectric polymer film, of a thickness for example of the order of 50 µm, applied by lamination (19) and through which at least one access recess (30) is formed after lamination on the active face (6); this obviously opening facing at least one connection pad (7) and being formed by laser cutting, mechanical such as stamping or the like. <Desc / Clms Page number 17> 7. Method according to one of claims 1 to 4, characterized in that the protective layer (14) is a polymeric and initially viscous dielectric material, applied (19) by screen printing; at least one access recess (30) is formed by a screen with masking zone during screen printing (19) through this screen printed layer, this obviously opening facing at least one connection pad (7). 8. Method according to one of claims 1 to 4, characterized in that the protective layer (14) is a polymeric dielectric material and initially viscous, such as ink or polymer adhesive, applied (19) jet for example from a matrix of nozzles with a section of the order of 20 μm for example; at least one access recess (30) is formed by programming during the projection (19) of the jets through this material, this obviously opening facing at least one connection pad. 9. Method according to claim 7 or 8, characterized in that the application (19) of an initially viscous material by screen printing and / or ink jet provides, for example before sawing (21) making the microcircuits of a unitary substrate plate (26), a step of polymerization by thermal, photonic, chemical or the like. 10. Method according to one of claims 1 to 9, characterized in that the protective layer (14) forms a barrier (15) for example with a thickness of 70 μm and having a substantially identical external profile as well as at right of the peripheral edge (4), against the overflow of the adhesive (9,13) inwards on the active face of the microcircuit (3), during the fixing step (22). <Desc / Clms Page number 18>  11. Method according to one of claims 1 to 10, characterized in that the microcircuit (3) is fixed (22) on the support (8) by placement in an insulating polymer adhesive deposit (9, 13) such that a resin; this adhesive (9.13) rising during placement against the edge (4) external peripheral of the microcircuit (3); for example the thickness of glue is between 80% and 100% of the thickness of the microcircuit (3) such as of the order of 180 μm, with a tolerance of the order of +/- 10% of the thickness microcircuit (3).

12. Method according to one of claims 1 to 11, characterized in that the step (23) aimed at connecting, after protection (19, 22), at least one interface element (10) to the corresponding stud (7), is carried out by depositing conductive material (11) such as resin or polymer adhesive charged with electrically conductive particles or intrinsically conductive polymer, for example by pad printing, inkjet, deposit with syringe or the like. 13. Method according to one of claims 1 to 12, characterized in that the connection material (11) is deposited on the fixing adhesive (9,13) and on at least one external part of the dielectric layer (14 ) of protection applied to the substrate, for example by covering a peripheral barrier (15) with this layer, while possibly a part (16) of the active face and / or of its passivation layer is devoid of this protective layer and / or covering by the connection material. 14. Method according to one of claims 1 to 13, characterized in that a connection contribution (23) called boss or "bump" is deposited after fixing (22) of the microcircuit (3) on its support, for example beforehand in the step providing for connecting the pad to the corresponding interface element; this contribution being disposed on this pad and intended to receive an electrical connection end portion of the interface element. <Desc / Clms Page number 19>

15. An electronic device (1) forming an intelligent portable object module (2) such as a smart card or electronic label, this device (1) comprising, once manufactured, at least: 'a microcircuit (3) provided with minus: 'a peripheral section (4) which has a conductivity on either side of the section, two main faces, one rear (5) and the other active (6) because provided with at least one stud connection (7) a dielectric support (8), on which is fixed the passive face of the microcircuit (3), by bonding an interface element (10) electrically connected to the pad by a conductive material called interface (11) 'a structure (12) for protecting the micromodule made of electrically insulating material called protection; characterized in that the protective structure (12) is applied to at most part of the active face (6) of the microcircuit (3), close to or in contact with the fixing adhesive (9) for example via a peripheral barrier (15) of this structure; this structure being at least partly covered by the conductive interface material (11) ensuring the connection. 16. Device (1) according to claim 15, characterized in that at least one insulating part (16) of the active face (6) of the microcircuit (3), for example part of its passivation layer, is released c that is to say devoid of any protective layer (14) and / or connection material. 17. Device (1) according to claim 15 or 16, characterized in that this device (1) is manufactured according to the method according to one of claims 1 to 14. <Desc / Clms Page number 20> 18. Equipment (17) such as an online and continuous production line for electronic devices (1) for intelligent portable objects (2) such as a smart card or electronic label, characterized in that this equipment (17) has a station (19) unitary deposition of an insulating protective layer (14) on a plate (26) grouping together several microcircuits, upstream of an assembly station (20) of the plate on a sawing vehicle (25); while downstream of a station (22) for fixing by bonding a unitary microcircuit (3) to a support, the equipment (17) has a station (23) for depositing a conductive connection material ( 11). 19. Equipment (17) according to claim 18, characterized in that it (17) is capable of implementing the method according to one of claims 1 to 14 and / or to manufacture the electronic device (1) forming a module according to one of claims 15 to 17. 20. An intelligent portable object (2), such as a smart card or electronic label, characterized in that it is manufactured on equipment (17) according to claim 18 and / or manufactured according to the method according to one of claims 1 to 14 and / or comprises an electronic device (1) according to one of claims 15 to 17.