FR2734984A1 - Surface Mounted Box for Integrated Circuit Micromodule - Google Patents

Abstract

The box is made into an enclosure by combining a micromodule (M) with protruding connectors (6) formed as contact zones flush w.r.t. each other onto a semiconductor substrate (S) which has corresponding contact areas (5) and tracks. The tracks cover the substrate surface and have end holes for surface mounted pins to be connected to the substrate.

Description

USE OF A MICROMODULE AS A HOUSING
SURFACE MOUNTING METHOD AND CORRESPONDING METHOD
The present invention relates to the use of an integrated circuit micromodule as a surface mounting box on an interconnection substrate.

 Surface mounting groups together a set of operations for depositing miniature components on the surface of a printed circuit or a screen-printed substrate of a hybrid circuit.

 The components are placed by automatic placement machines on the substrate, then welded. They do not have lead wires and do not require holes in the circuit for their attachment. They are packaged in honeycomb strips or tubes. They are sucked up and then transferred to the substrate.

 We call micromodule, the miniature assembly formed mainly of one or more integrated circuit chips and a connector formed of fine, substantially flat contact areas, and intended to be inserted in a thin information medium, of the type smart card or memory key, so that the connector is flush with the surface of the information carrier, the chip being embedded in the carrier. The connector has six to eight contact zones distributed in two rows which allow 5 to 8 standardized accesses to the chip: GND electrical ground, VCC logic supply, VPP programming voltage (not always used), RST reset, CLK clock and serial input / output of I / O data, two other zones being available for specific or future applications (8-way connector). International standards define the different characteristics of micromodules (ISO 7810 to 7816).

One of these characteristics is their low thickness.

Indeed, a micromodule typically has a thickness of less than 0.6 millimeter.

 Different industrial processes for manufacturing micromodules have been developed.

 A first known method consists mainly in transferring a chip onto a metal strip which supports the contact zones cut mechanically. The chip is connected by soldered wires to the different contact areas. The chip and the wires are then coated with a drop of protective resin. A strip of micromodules is obtained in series. Cutting makes it possible to obtain the individual micromodules which will then be inserted.

 To solve the problems of adhesion of the resin to the metallized grid and of overflowing of the resin on the contact areas of the connector, use is preferably made of dielectric molded or transferred hot on the grid, so as to produce a metallized support. single-sided, on which the chip is transferred to the dielectric side and connected by wires passing through perforations in the dielectric and welded to the contact areas.

 Another known method for producing a single-sided metallized support for micromodules uses a perforated dielectric strip, on one side of which metal is laminated. The metal is then etched to form the contact areas of the connector.

 Other methods finally use a double-sided metallized support film, one side for connection to the chip, the other side forming the connector.

 In an improvement, a metallic or dielectric enclosure is provided, which surrounds the chip and its connections. This enclosure is filled with protective resin (thermosetting silicone type or thermoplastic polyurethane type). A micromodule of perfectly reproducible and controlled shape and dimensions is obtained. The protective enclosure filled with resin effectively protects the chip and its connections from chemical attack and mechanical stress. Such a micromodule and corresponding method is for example described in the European patent application published under the number 0 391 790, filed on April 3, 1990 under the number 90 400909.

 These micromodules were mainly developed for so-called secure applications: disposable or rechargeable prepaid card, access control, subscription card, bank card, pay-TV card, single-service or multi-service card (...). For these micromodule applications, integrated circuit chips have been specially developed, which integrate different protection systems and comply with standardized connectors.

In simple memory chips, protection systems are provided in wired logic. Fuses are used to prevent write access to certain areas of the memory. A carrier code for the user of the card can be provided, to authorize read / write access to memory areas and to block the chip in the event of the presentation of an incorrect carrier code (stolen cards). An issuer code from the body that issues the card to the user can be contained in the chip, to block it if this code is wrong (false cards)
In microprocessor chips, more sophisticated protection systems can be used with in particular the implementation of cryptographic algorithms to secure data transfers, the systematic use of carrier and sender codes, the possibility of rehabilitating a card (chip unlocked) (...).

 A software operating system exists which also allows dynamic memory management or the loading of specific programs when the card is personalized.

 All these secure chips also include security sensors which control the operational conditions for using the card: CLK clock signal frequency not too low, logic supply voltage Vcc not too high, presence of the passivation layer final of the chip, (...).

 The sensors each deliver binary information, used directly to trigger a hardware security (blocking) or memorized to be used by an anomaly management program.

 Blocking of the chip is obtained for example by forcing the level of the reset signal (RST) to zero or by blocking access to strategic information.

 Standardized micromodule technology has therefore led to the development of integrated circuit chips with 5 to 8 outputs, highly secure both in terms of hardware and software, which have enabled the rise of micromodule cards that we know.

 The development of many electronic applications for IT or telematics requires securing access and data transfers. To this end, chip readers have been integrated into microcomputers, personalized memory key readers have been provided in decoders of chain-type channels.

 In the invention, an attempt has been made to solve this security problem in another way, inside electronic or computer equipment, on printed circuit boards or screen-printed substrate.

 What could have come to mind was to use a secure chip developed for micromodules, like a conventional electronic component, by placing it in a standardized semiconductor package, for example a DIL or SO package.

 However, we have seen that these chips use 5 to 8 outputs. In addition, the chips of the most complex micromodules occupy a large area. These chips therefore require large DIL or SO boxes with at least 8 or 16 outputs.

 However, the increasing complexity of electronic applications requires more and more miniaturization, especially in fields which are aimed at on-board installations or in private homes: it is necessary to offer equipment that is both efficient and space-saving.

Under these conditions, adding one or more boxes with 8 or 16 outputs to a printed circuit may prove difficult for some of these applications.

 To solve these various problems, the Applicant has had the idea of directly using the micromodules as surface mounting boxes on the interconnection substrates. In this way, a very advanced technology is used with regard to security, and which also allows high integration.

 As characterized, the invention therefore relates to the use of a micromodule as a surface mounting box on an interconnection substrate.

 To implement this invention, a first problem was encountered, due to the nature of the connector of the micromodule.

 The connector of a micromodule is in fact formed of fine, substantially planar contact zones in adhesion to a deformable dielectric surface. A small difference in the level of the contact zones is usual and a slight deformation of the dielectric surface possible. In practice, the connection surface of the micromodule is not perfectly flat. What is not a problem in the context of micromodule cards, for which the readers include perfectly adapted connectors, becomes an important problem when it comes to ensuring reliable contact and conduction between the contact zones of the micromodule and the contact pads on the surface of a printed circuit.

 Furthermore, according to the applicable ISO standards, the contact zones have a large surface area, of the order of 4 to 5 mm 2 and two zones of the same row are spaced approximately 0.2 to 0.84 mm. If you want to solder a micromodule on an interconnection substrate, even choosing an optimum spacing between the contact areas of the micromodule connector, within the framework of what is authorized by the applicable ISO standards, the risk of short circuit between contact areas is very important. For an electrical connection with contact pads on the surface of an interconnection substrate, the useful welding area for each contact must therefore be smaller than the surface of the contact area, so as to avoid short-circuits due to tolerances in rotation and in x and y automatic placement machines. Small contact pads are therefore chosen on the substrate, but the soldering may also spread naturally over the entire surface of the contact areas of the micromodule connector. There is still a risk of short circuits.

 To solve these connection problems, provision is made in one embodiment of the invention to provide a barrier to the expansion of solder between at least each useful contact area of the micromodule and a corresponding contact pad of the interconnection substrate.

 This barrier can be mechanical or physicochemical. It is preferably conductive.

 In another embodiment of the invention, it is provided that one end of the contact zones of the micromodule is free, to allow its bending, so as to form, around the periphery of the micromodule, pins suitable for surface mounting on an interconnection substrate.

 Another problem appeared in the lightness and the deformability of the connector surface of the micromodule. Indeed, a minimum space is necessary and imposed between a housing and the surface of the printed circuit, in particular to allow the cleaning of the printed circuit and prevent the formation of aggregates, and to allow a good electrical connection. However, if a hot air soldering operation is used for example, pressure must be applied to the micromodule to keep it in contact with the interconnection substrate during the supply of hot air below the micromodule. The micromodule may then deform or sink too much, which may cause the weld to overflow beyond the barriers provided.

 In the first embodiment of the invention, a mechanical stop is then provided between the micromodule and the interconnection substrate to impose the thickness of the solder interface.

Advantageously, this mechanical stop makes it possible to bond the micromodule to the substrate before the welding operation.

 In the other embodiment of the invention, the pins formed in extensions of the contact areas of the connector of the micromodule, serve both as a connector and as a mechanical stop.

 To make the routing and placement of the micromodules more reliable by automatic machines, use is preferably made of micromodules comprising the protective enclosure, seen above, which allows good reproducibility of the dimensions of the micromodule and gives the micromodule good protection against chemical attack and mechanical stresses.

Other characteristics and advantages of the invention will be better understood on reading the following description, made with reference to the appended drawings given by way of nonlimiting examples, in which
FIGS. 1 to 3 are side views of micromodules mounted on the surface on an interconnection substrate according to the invention,
FIG. 4 represents a view in median cross-section of an example of a strip of micromodules which include barriers to the expansion of solder and a mechanical stop according to an embodiment of the invention,
FIGS. 5 and 6 are perspective views from above (chip side) and from below (connection side) of a corresponding micromodule,
FIG. 7 is a sectional view of the connection of a contact zone of a micromodule on a contact pad of an interconnection substrate according to the first embodiment,
- Figure 8 shows a variant of Figure 7, with solder balls in the solid state.

 - Figures 9 and 10 are perspective views from above (chip side) and from below (connection side) of a micromodule according to another embodiment of the invention.

 Figures 1 to 3 show different forms of micromodules corresponding to the manufacturing methods already described and mounted on the surface of an interconnection substrate. The interconnection substrate may for example be a printed circuit, a screen-printed or etched substrate.

 FIG. 1 thus shows contact zones 1 of a micromodule M, on the surface of a dielectric screen 2 in a perforation or a recess of which the chip has been placed (not shown). The chip is connected to the contact zones by wires which pass through perforations in the screen and which are welded to the contact zones. A drop of protective resin 3 coats the chip and its connection wires.

 According to one embodiment of the invention, barriers to the expansion of solder 4 are provided between the connection surface formed by the contact zones 1 and the corresponding surface of a screen-printed substrate 5.

 These are mechanical or physicochemical barriers. Their thickness is less than or equal to the thickness e of the welding interface S.

 In the example of FIG. 1, their thickness is less than e.

 Preferably, these barriers are produced on the contact areas of the micromodule. They are for example produced by pad printing or screen printing when they are mechanical, or by spray through a screen when they are physico-chemical. When they are mechanical, provision can also be made to bond them to the micromodule.

 They are preferably conductive, which allows better thermal expansion of the entire connection. But there is no contraindication for them to be insulating.

 In the example shown in FIG. 1, the micromodule is also provided with solid state solder balls 6, deposited inside the barriers 4.

 In this case, if the barriers are conductive, these barriers advantageously serve as weld reinforcement after reflow.

 Finally, a mechanical stop 7 has been provided, which consists, in the example of FIG. 1, of a central element, placed between the central contact zone ZO of the micromodule and a corresponding zone of the substrate.

 FIG. 2 represents a micromodule mounted on the surface according to the same embodiment but with barriers 4 of the thickness of the welding interface S and without mechanical stop.

 The micromodule is here provided with a protective enclosure 8, which surrounds the chip and its connections and which is filled with protective resin. In the example shown, this enclosure is made of dielectric material, formed with the screen by molding.

 FIG. 3 represents another micromodule mounted on the surface of a screen-printed substrate 5 according to another embodiment of the invention. The micromodule here has a protective enclosure 9 made of metal. Contact zones are provided with a free end 10 and 11, around the periphery of the micromodule. These ends are bent so that they form surface mount housing pins. These pins advantageously serve both for connection to the interconnection substrate and as a mechanical stop.

 FIGS. 4 to 6 represent a micromodule of the type with a metal protective enclosure on which barriers and a mechanical stop have been formed in accordance with the first embodiment of the invention (FIGS. 1 and 2).

 FIG. 4 thus represents a strip of micromodules in series, as it can be obtained according to a continuous molding process of a perforated dielectric strip 13 on a metal grid 14 which carries the precut connectors. For each micromodule to be produced, a chip 15 is placed in a perforation 16 of the screen on a central zone ZO of the connector and the connection wires 17 of the chip, brought to contact zones Z3, Z4 of the connector, via d '' other perforations 18, 19 of the screen, and welded (automatic transfer technique on tape, TAB).

 A protective enclosure 20, here made of metal, is molded on the dielectric screen, which surrounds the chip 15 and its connections 17. This enclosure is filled with protective resin 21 (FIG. 5).

 According to one embodiment of the invention, barriers to the expansion of the weld are also produced.

 It will be recalled that the connector of the micromodule comprises 2 rows of 3 to 4 contact zones, Z1 to Z8 in FIGS. 4 to 6, with 1 contact zone Z2 which extends in the example in a central part of the connection surface , under the chip. This central zone ZO is not used to make an external electrical connection from the micromodule to the printed circuit.

 A barrier to the expansion of solder is produced for at least each of the contact zones which must be electrically connected to corresponding contact pads of the interconnection substrate. In practice, to simplify the process, these barriers can be produced for each of the contact zones of the connector of the micromodule. In the example shown in FIG. 6, the 8 contact zones Z1 to Z8 of the connector of the micromodule each comprise a barrier in the form of an enclosure P1 to P8.

 These barriers are for example mechanical. They can then be made of resin, by screen printing, on the metal grid 14. The resin used will preferably be a synthetic varnish such as that used to make the solder sparing layer of a printed circuit. It is a varnish that withstands the soldering temperature, which prevents short circuits between close conductors and protects against oxidation of copper conductors. This varnish is very resistant, hard surface and adheres as well on copper as on the substrate of the printed circuit (epoxy substrate for example).

 It can also be made of a conductive material (metal), which is advantageous in terms of thermal expansion for the connection.

 In the example shown in Figures 4 to 6, each micromodule also includes a mechanical stop.

In these figures, the mechanical stop comprises a central element denoted PO and positioned on the central contact zone ZO, which in the example is contiguous with the contact zone Z2. The mechanical stop can also include at least three elements P01, P02, P03 defining a plane, as shown in FIG. 7.

 The mechanical stop elements have a thickness of the order of the thickness e determined from the welding interface.

 They can be made of insulating or conductive material. For example, they are made of resin, by pad printing, screen printing or transfer. Finally, these mechanical abutment elements can be produced either on the connection surface of the micromodule, or on the surface of the interconnection substrate.

 In a variant represented in FIG. 7, provision is made in the manufacture of the strip of micromodules to deposit a ball or a ball 23 of solder paste in the solid state, for example a solid ball of tin-lead, in each of the intermediate speakers P1-P8, calibrated for the volume of the speaker. This solution is particularly favorable for the correct placement of the micromodule on the printed circuit (concentration of energy in the tip of the molten ball, which promotes the mechanical self-alignment of the micromodule on the printed circuit).

 The strip of micromodules obtained according to this first embodiment of the invention can therefore take on different aspects, depending on whether the solder balls or the mechanical stop elements are provided. It can be used directly by an automatic placement machine which cuts each micromodule.

 The strip of micromodules can also be cut and the individual micromodules obtained placed in honeycomb strips or in tubes, which are the usual supply magazines for automatic placement machines.

 The micromodules obtained are suitable for refusal welding in on contact pads of the interconnection substrate.

 For hot air or vapor phase welding, the solder paste which is sufficiently tacky is deposited by screen printing or transfer to further maintain the micromodules in place. Adhesive can also be provided at the mechanical stop, which makes it possible to hold the micromodule in place during the welding operation.

 FIG. 8 represents a sectional view of a connection of a contact zone 30 of a micromodule M according to the invention on a contact pad 31 of an interconnection substrate, for hot air welding .

 In the example, the tinned contact pad 31 is delimited by a layer of solder-resistant varnish 32.

 A barrier 33 produced according to the invention on the contact zone 30 contains a calibrated ball of solder 34 (Tin-Lead for example).

 A mechanical stop 35 according to the invention is produced on this same contact area 30 and bonded (36) to the substrate.

 A pressure P can then be applied to the micromodule and the supply of hot air locally removes the ball 34 which is crushed on the contact pad 31, the crushing being controlled by the mechanical stop 35 which maintains the thickness of the welding interface.

 We have seen that in practice, the 8 contact areas of a micromodule connector are not always used. In particular, for microprocessor chips, only 6 contact zones are used for the electrical interface. In some cases, micromodule connectors with 6 contact zones can then be produced. The bank card is an example. Or connectors with 8 contact zones are used with 2 non-useful contact zones, without electrical allocation.

 The invention obviously applies to these different variants. In particular, provision can be made to make the mechanical stops on the non-useful contact areas. It is also possible to connect these non-useful contact zones to corresponding pads of the interconnection substrate, according to the method of the invention.

 By using barriers to delimit the expansion of the solder and therefore delimit the connection zone between the micromodule and the interconnection substrate, or pins, the risks of short-circuit linked to the X, Y positioning tolerances are eliminated. and rotation of automatic placement machines.

 Preferably in the embodiment with barriers, provision is made for the connection zone for a contact zone of the micromodule, delimited by an intermediate enclosure, not to exceed 1 mm2 approximately. We can then choose an optimum spacing between the contact areas of the micromodule connector, within the framework of what is authorized by ISO standards, so as not to favor the formation of short circuits.

 Finally, the barriers and stops can be of any shape. In the examples shown, the enclosures are annular and the stops are cubic in shape.

 Another embodiment of the invention is shown in Figures 9 and 10, which consists in transforming the contact areas of the connector of a micromodule into surface-mounting pins.

 Thus, according to the invention, provision is made in this case for the contact zones to be provided with free ends which extend beyond the periphery of the micromodule. Provision is made, for example, for the strip of micromodules seen in FIG. 4, which comprises a strip of dielectric screen molded on the metal grid which forms the contact areas, to be exposed to light to make an opening in the dielectric screen. to allow the strip to be cut in these openings. Individual micromodules are obtained with free ends of metal on their periphery, which are the tabs which retained the precut contact areas of the connector to the grid 13. A bending operation then makes it possible to form pins B1 for surface mounting of the micromodules by electrical welding. The different shapes of surface-mounting pins can be produced according to this method which is not limited to the shape given as an example in FIGS. 9 and 10. The pins thus formed then advantageously serve both for connection and mechanical stop.

 In the case of these micromodules with surface-mounting pins according to the second embodiment of the invention and as seen in relation to FIGS. 9 to 10, several pins can be provided per contact zones. It suffices that a pre-cut contact zone is attached to the support metal grid by several tabs. The cutting is carried out far from the contact zones, so as to keep these tabs as free ends for each contact zone. These tabs can then be arched.

The cutting and bending operation can be carried out by the automatic placement machine comprising the appropriate tools.

 The various embodiments and variants described allow a reliable and industrial surface mounting of micromodules. The deformability and lightness of the micromodule are judiciously compensated for by the mechanical stops which can be obtained by simple screen printing, or by the pins. These inexpensive adaptations also make it possible to limit the risks of short circuit linked to the shape of the contact zones of the micromodule.

Claims (12)

 1. Micromodule (M) characterized in that it is used as a surface mounting box on an interconnection substrate (S).  2. Micromodule comprising a standardized connector formed of contact areas flush with the surface, characterized in that it is used as a surface mounting box on an interconnection substrate, said contact areas being used for this to make the ranges of surface mounting of the micromodule on the substrate.  3. Micromodule for use as a surface-mounting box according to claim 1, characterized in that the contact zones (Z1-Z8) of the connector of the micromodule are extended by tabs on the periphery of the micromodule, intended to be arched for forming pins (B1) for surface mounting said pins serving both for connection with the substrate and for mechanical stop.  4. Micromodule for use as a surface mounting box according to claim 1, characterized in that it comprises a barrier to the expansion of solder (4) on at least each useful contact area of the connector of the micromodule.  5. Micromodule according to claim 3, characterized in that the barrier is in the form of an enclosure.  6. Micromodule according to claim 4, characterized in that the barrier is physico-chemical or mechanical.  7. Micromodule according to any one of claims 3 to 5, characterized in that the barrier is conductive.  8. Micromodule according to any one of claims 3 to 6, characterized in that it comprises a calibrated ball of solder (6) in the solid state inside each of the barriers (4).  9. Micromodule according to any one of claims 3 to 7, characterized in that it further comprises a mechanical stop (6) produced on the surface of the connector.  10. Micromodule according to claim 8, characterized in that the mechanical stop comprises a central element (PO), on a central zone (ZO) of the connector of the micromodule.  11. Micromodule according to claim 8, characterized in that the mechanical stop comprises at least three elements (P01, P02, P03) distributed over the connector so as to form a plane.  12. Strip of micromodules in series according to any one of claims 2 to 10.