Abstract:
Memory Cards containing Integrated Circuits and other electronic components (e.g. resistors) in a variety of form factors having high quality external surfaces of polycarbonate, synthetic paper (e.g. Teslin), or other suitable material (e.g. PVC) can be made through use of injection molded thermoplastic material or thermosetting material that becomes the core layer of said Memory Cards and similar devices. The object of the invention is to provide the following properties to Memory Cards: rapid production cycle, high volume manufacturing throughput, security, electronics protection, better tamper resistance, durability, and highly reliable complex electronics encapsulation, achieved through a process utilizing low temperature and low pressure.

Description:
BACKGROUND OF THE INVENTION 
     In recent years, consumer electronic devices such as digital cameras, Personal Digital Assistants (PDAs), smart phones, and digital audio and video recorders have driven a strong market demand for removable data storage components. The electronics industry has responded to this demand with products known generically as “memory cards.” A memory card usually contains one or more semiconductor memory chips within an industry-standard housing with dimensions that allow it to be used in conjunction with different devices from various manufacturers. Memory cards typically also have connectors on an external surface that allow electrical connections to the circuitry of consumer electronic devices. Examples of types of memory cards include PC Cards, MultiMedia Cards, CompactFlash Cards, and Secure Digital Cards. These devices are made in accordance with standards promulgated by trade associations such as the Personal Computer Memory Card International Association (“PCMCIA”) and the MultiMedia Card Association (“MMCA”). 
     An exemplary memory card, namely, a MultiMedia Card (“MMC”)  10 , is illustrated in top view, cross-sectional side view, and bottom view in  FIGS. 1–3 , respectively. The MMC illustrated has standardized dimensions of 32 mm long, 24 mm wide, 1.4 mm thick, and typically includes a memory capacity of between 2 and 256 megabytes (“MB”) of memory, which is accessed through seven contacts  11  located on the bottom surface of the MMC using, e.g., a standard serial port interface (“SPI”) interface. A simple chamfer  12  on one corner of the MMC prevents incorrect insertion of the MMC into a connector in a host device. 
     The exemplary prior art MMC shown in  FIGS. 1–3  comprises a rectangular substrate  13 , such as a printed circuit board (“PCB”), and one or more semiconductor memory dies  14  or “chips” mounted on and electrically connected thereto using, e.g., a layer of adhesive  15  and conventional wire bonds  16 , respectively. Surface mounted passive components, e.g., resistors, may also be mounted on and connected to substrate  13 . Contacts  11  are connected through substrate  13  to memory circuits defined by foregoing components and serve as input-output terminals of card  10 . 
     When the components have been mounted on and connected to the substrate  13 , prior art methods included a step in which chip  14  is protectively encapsulated by a “glob-topping” process. This step was necessary due to the high-pressure, high-temperature injection of thermoplastic material that would occur at a later stage. The high-pressure injection and high temperature can damage a microchip and other small electronic components, particularly wire bonds. In the glob-topping step a glob of a viscous encapsulant is dispensed onto the top surface of the chip and is allowed to flow over the chip&#39;s sides to the surface of the substrate. The encapsulant is cured to form a protective envelope  18  over the chip. An external cover or housing  19  (shown by the dotted outline in  FIG. 1 ) of thin sheet metal or plastic is installed over the substrate  13  assembly by embedding the top surface of the assembly in a bed of adhesive contained in the housing  19 . 
     Prior art methods for making memory cards are, to a large degree, concerned with properly positioning and fixing electronic components, modules or assemblies inside the memory card. This concern is due to the fact that if the electronic components are not properly affixed they will be moved to random positions during injection of the thermoplastic material into a card-forming cavity. This is a particular problem in the prior art processes because the injection occurs under the influence of rather high pressures. Prior methods for making memory cards included the use of relatively large, mechanical holding devices having hard, sharply defined bodies for holding the electronic components in place during injection of thermoplastic materials. The use of such holding devices can limit the positioning options for the electronic components in the memory card. The positioning limitation also may cut down on the size and number of electronic components that can be placed in such memory cards. This limitation in turn limits the amount of memory that can be put into an MMC. 
     Additionally, due to differences in the coefficients of expansion of the materials used to make these relatively large holding devices—relative to the coefficient of expansion of the other elements of such cards—deformations often appear on the external surfaces of finished cards that contain such electronic component holding devices. That is to say that surface deformations can result from the mere presence of such holding members in the body of the card as it experiences different temperatures and pressures during its manufacture. Such deformations are, at best, unsightly; at worst, they may prevent the card from lying completely flat in the card-receiving receptacles in certain card reading machines. 
     Some memory card manufacturers have dealt with this problem by reducing the size of such holding devices or by using glues to securely position their electronic components in card-forming cavities during the thermoplastic injection process. The use of glues to secure electronic components has, however, resulted in another set of problems. These problems are due to the fact that most commercially available, fast-curing glues that are used to fix such electronic components in place are often characterized by their high degree of shrinkage. Moreover, relatively large volumes of glue are needed to fix the electronic components. Use of relatively large volumes of high-shrinkage glue tend to wrinkle and otherwise deform the region of the plastic sheet or layer to which such glues are applied. This wrinkling can transmit through the thin body of the memory card and cause the outer surface of the card to take on a local wave-like character. Beyond certain tolerances, these wave-like bends are unacceptable in the memory card industry because a deformed memory card will be inoperable in certain devices. 
     One additional limitation, which was touched on above, in the manufacture of prior art memory cards is that they are typically produced with prior art processes that involve the injection of filled epoxy resin or high-temperature, high-pressure thermoplastic injection into molded forms. In addition to the fact that a high-pressure, high-temperature injected material may stress or damage the electronic components of the card, it also takes a relatively long time to set and cool in the mold. Epoxy resins undergo a chemical reaction following injection, which can damage the electronic components of the memory card. What is needed is a method for producing memory cards that does not require providing a “glob-top” for memory die assemblies, with a rapid cure time and rapid manufacturing cycle time, and without the use of internal holding measures that could damage the memory card electronics. 
     SUMMARY OF THE INVENTION 
     It is therefore an object of this invention to provide a Memory Card or similar device with a thickness ranging from approximately 0.76 mm (the thickness of a conventional credit card) to approximately 5.0 mm that contains securely encapsulated Integrated Circuits and/or other electronics (e.g. a resistor) and with high quality exterior surfaces on which sophisticated graphics may be printed. The bottom surface of the Memory Card must include external contacts for electronic communication with other devices. It is additionally an object of this invention to securely encapsulate the electronics in a memory card using a low-pressure, low-temperature process in order to obviate the need for “glob-topping” the electronics. Removing the glob-topping process will save time in the processing of memory cards and will additionally provide valuable space inside of the memory card for additional memory or other electronic components. It is additionally an object of this invention to reduce manufacturing cycle time with a low-temperature process that improves production efficiency. A low-temperature process allows memory cards to be produced with less energy and enables production cycle time to be greatly reduced, thus improving manufacturing output. 
     This and other objects of the invention are achieved by providing a multi-layer Memory Card with an outer layer of material such as Teslin™ or other synthetic paper or suitable material (e.g. PVC, PC), with a core layer of injected polymeric material that securely encapsulates an Integrated Circuit (e.g. Multimedia card die assembly), and securely bonds to the outer layer of Teslin™ or other suitable material. 
     The use of low shrinkage glue to pedestal the electronic components above the bottom layer of the device facilitates an even flow and a complete encapsulation of the electronics by injected polymeric material. The mounds of low shrinkage glue positioned on the bottom layer of the device create and maintain a void space of approximately 0.1 to 0.15 mm to allow injected polymer to fill said void space and cover the top surface of the bottom layer and the bottom surface of the top layer, with no voids or pockets and with even and complete distribution of the polymer material in the void space below and above the electronics. Alternatively, the electronic components may be placed directly on a bottom mold without use of a bottom layer. In this way, the bottom of the electronic components comprises the bottom surface of the device. 
     The object of the Teslin™, PVC, or other suitable material inlay sheet design is to enable the production of inlays, which are the electronic components, with multiple inlays per sheet. For example,  FIG. 6  illustrates a 16×10 array of inlays (a total of 160 Memory Cards). 
     The inlays are produced on a single continuous sheet, which is then cut by a machine tool in a form that allows the Memory Card perimeter to be covered by the injected polymer. 
    
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
         FIGS. 1–3  depict a prior art memory card in a top view cross-section, side view cross section, and bottom view, respectively. 
         FIG. 4  is a cut-away side view of a layer or sheet of a synthetic paper (e.g. Teslin™) or plastic material (e.g., PVC) as used to make prior art Memory Cards. This view is shown before ( FIG. 4(   a )) and after ( FIG. 4(   b )) a drop of a prior art, “high shrinkage” glue is allowed to cure on that layer of synthetic paper or plastic material. 
         FIG. 5  is a cut-away side view of a Memory Card made according to the teachings of this patent disclosure. 
         FIGS. 6 and 7  are cut-away side views of a mold tool set up for making a first preferred embodiment of an Memory Card of this patent disclosure wherein certain Memory Card components (e.g. Multimedia card die assembly) are shown before a liquid polymeric material is injected between the Memory Card&#39;s top and bottom layers (see  FIG. 6  and after (see  FIG. 7 ) the polymeric material is injected into a void space between the top and bottom layers and thereby filling said void space with a polymeric material and cold forming the top layer of the Memory Card to the contour of the top mold&#39;s Memory Card-forming cavity. 
         FIG. 8  is a cut-away view showing a mold tool being removed from a precursor Memory Card body formed by the system generally depicted in  FIG. 7 . 
         FIG. 9  depicts a mold tool system that is capable of making 160 Memory Cards (with dimensions of approximately 24 mm×32 mm) simultaneously. 
         FIG. 10  is a cut-away side view of a finished Memory Card made without a separate bottom layer. 
         FIGS. 11 and 12  are cut-away side views of a mold tool set up for making a first preferred embodiment of an Memory Card of this patent disclosure wherein certain Memory Card components (e.g. Multimedia card die assembly) are shown before a liquid polymeric material is injected between the Memory Card&#39;s top layer and the electronic component. The polymeric material is injected into a void space between the top layer and the electronic components thereby filling the void space with a polymeric material and cold forming the top layer of the Memory Card to the contour of the top mold&#39;s Memory Card-forming cavity. 
         FIG. 13  is a cut-away view showing a mold tool being removed from a precursor Memory Card body formed by the system generally depicted in  FIG. 12 . 
     
    
    
     DETAILED DESCRIPTION OF THE INVENTION 
       FIGS. 4(   a ) and  4 ( b ) illustrate a problem involved with the prior art methods of making Memory Cards.  FIG. 4(   a ) depicts, in cut-away cross section, a sheet or layer of a plastic material  40  (e.g., a sheet or layer of polyvinyl chloride, polyurethane, etc.) having a top surface  41  and a bottom surface  42 . Such sheets will generally have a thickness  43  ranging from about 0.075 mm to about 0.25 mm. A mound, drop, or dollop of a liquid or semi-liquid, high shrinkage, glue  44  is depicted as being recently dispensed on the top surface  41  of the plastic sheet  40  shown in  FIG. 4(   a ). The mound of recently dispensed glue  44  depicted in  FIG. 4(   a ) is shown having an initial width W 1 .  FIG. 4(   b ) shows (in exaggerated form) the results of curing the mound of glue  44  shown in  FIG. 4(   b ) to a smaller mound of cured glue  44 ′. The width W 2  of the mound of cured glue  44 ′ depicted in  FIG. 4(   b ) is considerably less than the width W 1  of the mound of the newly laid liquid or semi-liquid glue  44  in  FIG. 4(   b ). For the sake of simplicity, the decrease or shrinkage from the original width W 1  to W 2  (i.e., ΔW) of the mound of newly dispensed, high shrinkage glue is represented in  FIG. 4(B)  by the dimensions “½ ΔW,” on the left side of the mound of and a comparable “½ ΔW” on the right side of said mound of cured glue  44 ′. Such curing is also depicted by a decrease in the volume of the original mound of glue  44 . For example, this decrease in volume may be as much as 20 to 30 percent in many high shrinkage glues. 
     As previously noted the concept of a “high shrinkage” glue versus a “low shrinkage” glue also can be addressed in terms of the decrease in volume of a cured glue relative to the volume of that glue in its newly laid state. 
     The curing process associated with high shrinkage glues causes the mound of glue  44  depicted in  FIG. 4(   a ) to shrink from an initial size which can be thought of as having an initial width W 1  (wherein the mound of glue is in a semi-liquid or tacky state) to a final width W 2  (wherein the cured glue  44 ′ is in a substantially solid state) and that this high degree of shrinkage (e.g., greater than about 15 percent—and often as much as 20–30 percent) causes the top surface  41  of the layer or sheet of plastic material to “wrinkle up” or otherwise deform, e.g., form wrinkles  45  in  FIG. 4(   b ). Such deforming actions create forces in the relatively thin layer (e.g., 0.075 to 0.25 mm thick) of plastic material  40 . These forces are transmitted to the bottom surface  42  of that layer of plastic material  40 . These transmitted forces, in turn, cause deformations  46 , (curves, bends, waves, ripples, wrinkles, etc.), in the bottom surface  42  of the plastic layer  40 . Any such deviations from a flat, smooth surface are regarded as highly undesirable deformities by the Memory Card industry and, hence, must be minimized to the fullest extent possible. Achievement of Memory Card surfaces having no such waves, bends, wrinkles, or other imperfections is one of the primary objects of the processes of this patent disclosure. 
       FIG. 5  depicts a cut-away side view of a Memory Card  50  made according to the teachings of this patent disclosure. In its finished form, such a Memory Card  50  will be comprised of a top layer  51 , a bottom layer  52 , and a center or core layer  53  in which the Memory Card&#39;s electronic components (e.g. Multimedia die assembly  54  that includes a substrate  55  and contact pads  56 , etc.) are embedded in a thermosetting polymeric material  57  (e.g., an initially liquid or semi-liquid thermosetting resin) that, upon curing, constitutes the center or core layer  53  of finished Memory Card  50 . The thermosetting material  57  that eventually becomes the core layer  53  of Memory Card  50  is injected into the void space between the top layer  51  and bottom layer  52 . 
     The void space is of height  58  and extends from one side of the card to the other. As described herein above, prior art methods of making memory cards involved injection of epoxy resins that chemically reacted to solidify and form the body of a memory card. These reactions are potentially dangerous to sensitive electronic components such as a microprocessor. Alternatively, prior art methods involved high-pressure injection of a high-temperature thermoplastic material. The high-pressure and temperature of prior art methods of injection is also dangerous for electronic components, which is why “glob-topping” to protect the electronic components is common practice when using the prior art methods. The configuration of the electronic components shown in  FIG. 5 , which does not include a protective “glob-top,” would not be usable with either epoxy resins or high-pressure injected high-temperature thermoplastic materials. Lastly, both epoxy resins and high-temperature thermoplastics when injected into a mold take a considerable amount of time to cure. The lengthy curing and cooling times required when using high-temperature thermoplastics and high-pressure injection greatly slows the process of producing devices. 
     For these reasons the injected polymeric material  57  provides significant advantages by being injected under the relatively cold, low pressure forming conditions employed in applicant&#39;s process. 
     In any case, such thermosetting polymeric materials will be injected into, and fill, the void space  58  defined between the inside surface  59  of the top layer  51  and the inside surface  60  of the bottom layer  52 . Upon curing, the polymeric material  57  of the core layer  53  should bond or otherwise adhere to both the inside surface  59  of the top layer  51  and the inside surface  60  of the bottom layer  52  to produce a unified Memory Card body. Such adherence can be aided by treating the inside surfaces  59  and  60  of the top and bottom layers in any one of several ways. For example, bonding agents known to this art (e.g. chloro-polyolefins) may be employed to enhance bonding between the core layer-forming thermoset material and the material(s) from which the top and bottom layers are made (e.g., Teslin, PVC). By way of example only, Minnesota Mining and Manufacturing&#39;s base primer product 4475 RTM can be used for this bond enhancing purpose, especially when the top or bottom layer material is PVC. Other treatments that can be applied to the inside surfaces of the top and/or bottom layers could include plasma corona treatments and acid etching. 
     The Memory Card&#39;s thickness  61  is defined by placement of the mold faces (not shown in  FIG. 5 ) as the thermoset material is injected into the void space  58  as part of the cold, low pressure forming process of this patent disclosure. In effect, the injection of the thermoset material into the void space  58  between the top and bottom layers fills any portion of that void space  58  that is not otherwise occupied by the electronic components or by the mound(s) of low shrinkage glue  62  upon which the electronic components are placed. 
     Next, it should be noted that the Memory Card&#39;s electronic components (e.g., Multimedia die assembly substrate  55 , Memory chip  54 , etc.) are preferably positioned above the inside surface  60  of the bottom layer  52  through use of one or more drops or dollops of applicant&#39;s low shrinkage glue  62 . As described herein above, prior art methods of making memory cards did not employ glue to pedestal the electronic components of the memory card. This is due to the fact that the prior art methods involve injection of epoxy resins or high-pressure, high-temperature thermoplastic materials, both of which would damage the glue. Also, and more importantly, because the prior art methods involve injection of epoxy resins or high-pressure high temperature thermoplastic materials, the electronic components have to be “glob-topped” and it is therefore unnecessary to pedestal the electronics. 
     In applicant&#39;s method, the electronic components are most preferably placed on top of two or more mound(s) of glue  62 , etc. in the manner generally suggested in  FIG. 5  so that the incoming liquid or semi-liquid polymeric material will flow under such electronic components as well as immerse these components from above and from their sides. In other words, in the more preferred embodiments of this invention the mound(s) of glue  62  will serve as one or more “pedestal(s)” upon which the electronic components are placed so that the underside of the electronic components do not come into direct contact with the top surface  60  of the bottom layer  52 , but rather are immersed in the incoming thermoplastic material  57 . This design enables these electronic components to better resist any flexion and/or torsion forces the Memory Card may encounter upon either of its major outside surfaces or on any of its four outside edge surfaces. In some of the more preferred embodiments of this invention these electronic components (e.g., Memory chip  54 ) will be positioned by the glue at a distance  63  of from about 0.075 mm to about 0.13 mm above the inside surface  60  of the bottom layer  52 . 
       FIGS. 6 and 7  are contrasted to illustrate a first preferred embodiment of applicant&#39;s methods for making Memory Cards and similar devices. That is to say that  FIG. 6  depicts a particularly preferred embodiment of this invention wherein the flat, top layer or sheet  51  of synthetic paper such as Teslin™ or plastic material  51  such as PVC is shown before it is cold, low pressure formed according to the teachings of this patent disclosure. In other words,  FIG. 6  depicts the mold tool set-up just prior to the injection of the polymeric material and wherein a flat, top layer  51  (e.g., a flat sheet of PVC) is shown as it is initially placed under a Memory Card-forming cavity of the top mold  64  and a bottom layer  52  (e.g., another flat sheet of PVC) is shown as it is placed over a bottom mold  65 . Again, however, in some less-preferred, but still viable, embodiments of applicant&#39;s processes the top layer  51  may be pre-molded or at least partially pre-molded, preferably, to the general contour of the Memory Card-forming cavity in the top mold  64 . 
     By way of comparison, the bottom mold  65  has no cavity comparable to the cavity in the top mold  64 .  FIG. 7  depicts the effects of injecting the thermoset polymeric material  57  into the void space between the top and bottom layers  51  and  52 . Thus,  FIG. 7  shows the top layer  51  after it has been molded into a Memory Card-forming cavity  66  in the top mold  64 . 
     Referring to  FIG. 6 , a nozzle  67  for injecting a liquid or semi-liquid, thermoplastic or thermosetting polymeric material  57  is shown being inserted into an orifice  68  that leads to the void space that is defined between the inside surface  59  of the top layer  51  and the inside surface  60  of the bottom layer  52 . The distance between the top surface  69  of the top layer  51  and the bottom surface  70  of the bottom layer  52  is depicted by distance  78 . The void space is shown extending from orifice  68  to the opposite end of the juxtaposed top layer  51  and bottom layer  52 . In other words, in  FIG. 6  a portion of the outside surface  69  of the top layer  51  is not yet in contact with the inside surface  72  of the Memory Card-forming cavity  66  of the top mold  64 . By way of contrast, the outside surface  70  of the bottom layer  52  is shown in substantially flat, abutting contact with the inside surface  74  of the bottom mold  65 . 
     In both  FIGS. 6 and 7  the electronic components of the Memory Card (e.g., its substrate  55 , memory chip  54 , etc.) are shown positioned above the inside surface  60  of the bottom layer  52 . By way of example only, such electrical components are shown pedestaled on two dabs or dollops  62  of applicant&#39;s low shrinkage glue. These glue pedestals hold the electronic components far enough above the inside surface  60  of the bottom layer  52  (e.g., from about 0.075 mm to about 0.13 mm) that the incoming thermoset polymeric material  57  can flow in to the region  75  under the electrical components as well as the regions above these electronic components. Again, such glue pedestal arrangements are preferred because the presence of the thermoset polymeric material under the electronic components tends to augment the protection of such electronic components against any forces or shocks that may be received by the outside surfaces (i.e., the outside of the bottom layer and/or the outside of the top surface) of the Memory Card. 
     In  FIG. 6  the top mold  64  is shown having a cavity  66  which defines the surface contour of the top of the Memory Card to be formed during the injection process. To this end, the injection of the liquid or semi-liquid thermoset polymeric material  57  should be under pressure and temperature conditions such that the top layer  51  is cold, low pressure, formed into the cavity  66  of the top mold  64 .  FIG. 7  shows how the cold, low pressure forming process of this patent disclosure has in fact conformed the top surface  69  of the top layer  51  to the configuration of the Memory Card-forming cavity in the top mold  64 . Again, the bottom surface  70  of the bottom layer  52  is shown in  FIG. 7  molded against a substantially flat inside surface  74  of the bottom mold  65 . This is a particularly preferred arrangement for making the Memory Cards of this patent disclosure. 
     In  FIGS. 6 and 7 , a front lip region  76  of the top mold  64  and a front lip region  77  of the bottom mold  65  are shown spaced apart from each other by a distance  78 ′ that (taking into consideration the thickness of the top and bottom layers  51  and  52 ), in effect, defines the distance the width of the void space between top layer  51  and the bottom layer  52  at lip regions  76  and  77  of molds  64  and  65 , respectively. This distance should be such that the thermoset polymeric material  57  can be injected into the void space over the entire length of the Memory Card. The counterpart distance  58  of the mold device setting on the right side of the system shown in  FIG. 6  may differ from that of distance  78 ′ on the left side. In any case the distance  58  should be such that the distance  58 ′ defined between the inside surface  59  of the top layer  51  that passes through the rear lip  79  of the top mold  64  and the inside surface  60  of the bottom layer  52  that passes through the rear lip  80  of the bottom mold  65  is very small—but still finite. That is to say that this very small distance  58 ′ should be large enough to allow gases  81  (e.g., air, polymeric ingredient reaction product gases, etc.) in the void space that originally existed between the top and bottom layers  51  and  52 , respectively (see again,  FIG. 6 ), and excess polymeric material to be exhausted from said void space, but still be small enough to hold the injection pressures used to inject the thermoset polymeric material  57 . The distance  58 ′ is preferably sized large enough to allow even thin layers of the liquid polymeric material  57  itself to be “squirted” or “flashed” out of the void space—and thus allowing all gases residing in, or created in, the void space to be expunged out of said void space and, indeed, out of the mold system itself. Thus, all such gases  81  are completely replaced by the incoming liquid thermoset material  57 . This gas exhaust technique serves to prevent gas bubbles from forming in the body of the thermoset material  57  that eventually (i.e., upon curing of the thermoset material) comprises core layer  53  as shown in  FIG. 7 . 
       FIG. 8  shows a semi-finished or precursor Memory Card of the type shown in  FIG. 7  being removed from a mold system. Section lines  84  and  86  respectively show where the left end and right end of the precursor Memory Card can be cut or trimmed away to create the sharp edges and precise dimensions of a finished Memory Card. In this case the distance  82  is about 32 millimeters. 
       FIG. 9  illustrates a molding procedure being carried out according to some of the preferred embodiments of this patent disclosure wherein  160  Memory Cards  50  with dimensions of approximately 24 mm×32 mm are being molded simultaneously. 
       FIG. 10  illustrates a finished Memory Card  122  made using an alternate embodiment of the present invention in which an electronic component (in  FIG. 10 , the memory die assembly is comprised of substrate  126 , memory die  134 , external electrical contacts  133 , and additional components) is used as the bottom layer, and no additional bottom layer is necessary. 
       FIGS. 11 and 12  illustrate this second embodiment of applicant&#39;s methods for making Memory Cards and similar devices. That is to say that  FIG. 11  depicts a particularly preferred embodiment of this invention wherein a flat, top layer or sheet  124  of synthetic paper such as Teslin™ or plastic material  124  such as PVC is shown before it is cold, low pressure formed according to the teachings of this patent disclosure. In other words,  FIG. 11  depicts the mold tool set-up just prior to the injection of the polymeric material and wherein a flat, top layer  124  (e.g., a flat sheet of PVC) is shown as it is initially placed under an Memory Card-forming cavity of the top mold  144  and an electronic component comprised, for example, of a substrate  126 , memory die  134 , and external contacts  133 , is shown as it is placed over a bottom mold  146 . Again, however, in some less-preferred, but still viable, embodiments of applicant&#39;s processes the top layer  124  may be pre-molded or at least partially pre-molded, preferably, to the general contour of the Memory Card-forming cavity  164  in top mold  144 . 
     By way of comparison, the bottom mold  146  has no cavity comparable to the cavity in the top mold  144 .  FIG. 12  depicts the effects of injecting the thermoset polymeric material into the void space  136  between the top layer  124  and the electronic component.  FIG. 12  shows the top layer  124  after it has been molded into a Memory Card-forming cavity  164  in the top mold  144 . 
     A nozzle  148  for injecting a liquid or semi-liquid, thermoplastic or thermosetting polymeric material  134  is shown being inserted into an orifice  149  that leads to the void space  136  that is defined between the inside surface  138  of the top layer  124  and the inside surface of the electronic component. The distance between the top surface  155  of the top layer  124  and the bottom surface  158  of the Memory Card is depicted by distance  125 . The void space  136  is shown extending from the left end to the right end of the juxtaposed top layer  124  and the electronic component. In other words, in  FIG. 1  the outside surface  155  of the top layer  124  is not yet in contact with the inside surface  156  of the Memory Card-forming cavity  164  of the top mold  144 . By way of contrast, the outside surface  158  of the electronic component is shown in substantially flat, abutting contact with the inside surface  160  of the bottom mold  146 . 
     In  FIG. 11  the top mold  144  is shown having a cavity  164 , which defines the surface contour of the top of the Memory Card to be formed during the injection process. To this end, the injection of the liquid or semi-liquid thermoset polymeric material  134  should be under pressure and temperature conditions such that the top layer  124  is cold, low pressure, formed into the cavity  164  of the top mold  144 .  FIG. 12  shows how the cold, low pressure forming process of this patent disclosure has in fact conformed the top surface  155  of the top layer  124  to the configuration of the Memory Card-forming cavity  164  in the top mold  144 . Again, the bottom surface  158  of the electronic component is shown in  FIG. 7  molded against a substantially flat inside surface  160  of the bottom mold  146 . 
     In  FIGS. 11 and 12  a front lip region  166  of the top mold  144  and a front lip region  168  of the bottom mold  146  are shown spaced apart from each other by a distance  170  that (taking into consideration the thickness of the top layer  124  and electronic component), in effect, defines the distance the width of the void space between the top layer  124  and the electronic component at these lip regions of the two molds  144  and  146 . This distance  170  should be such that the thermoset polymeric material  134  can be injected into the void space  136  over the entire length of the Memory Card. The counterpart distance  170 ′ of the mold device setting on the right side of the mold system may differ from that of distance  170  on the left side. In any case the distance  170 ′ should be such that the distance  137  defined between the inside surface  138  of the top layer  124  that passes through the rear lip  167  of the top mold  144  and the inside surface of the electronic component that passes through the rear lip  169  of the bottom mold  146  is very small—but still finite. That is to say that this very small distance  137  should be large enough to allow gases  172  (e.g., air, polymeric ingredient reaction product gases, etc.) in the void space  136  that originally existed between the top layer  124  and the electronic component (see again,  FIG. 11 ) and excess polymeric material to be exhausted from said void space  136 , but still be small enough to hold the injection pressures used to inject the thermoset polymeric material. The distance  137  is preferably sized large enough to allow even thin layers of the liquid polymeric material  134  itself to be “squirted” or “flashed” out of the void space  136 —and thus allowing all gases residing in, or created in, the void space  136  to be expunged out of said void space and, indeed, out of the mold system itself. Thus, all such gases  172  are completely replaced by the incoming liquid thermoset material  134 . This gas exhaust technique serves to prevent gas bubbles from forming in the body of the thermoset material  134  that eventually (i.e., upon curing of the thermoset material) comprises the core layer  128  ( FIG. 10 ). 
       FIG. 13  shows a semi-finished or precursor Memory Card of the type shown in  FIG. 12  being removed from a mold system. Section lines  284  and  286  respectively show how the left end and right end of the precursor Memory Card can be cut or trimmed away to create the sharp edges and precise dimensions of a finished Memory Card. In this case the distance  274  is about 32 millimeters. 
     While this invention has been described with respect to various specific examples and a spirit that is committed to the concept of the use of special glues and gluing procedures, it is to be understood that the herein described invention should be limited in scope only by the following claims.