Abstract: An encapsulated microelectronic package includes a fluid conducting cooling tube directly coupled to one or more semiconductor chips, with the encapsulant being molded over the semiconductor chips and portions of the cooling tube in proximity to the semiconductor chips. The encapsulant immobilizes the cooling tube with respect to the semiconductor chips, and the cooling tube and encapsulant are designed to minimize differences in their coefficients of thermal expansion relative to the semiconductor chips.

Abstract: An electronic module includes a substrate, at least one surface mounted integrated circuit (IC) component and an underfill material. The substrate includes a plurality of electrically conductive traces, formed on at least one surface of the substrate, and the component is electrically coupled to at least one of the conductive traces. The underfill material is positioned between the component and the substrate and provides at least one pedestal that supports the component during encapsulation. The underfill material, when cured, maintains the integrity of the electrical connections between the component and the conductive traces.

Abstract: An electronic module and method that enable circuitry required by one form of the module (e.g., a developmental unit) to be omitted in a second form of the module (e.g., a production unit), without necessitating additional changes in the module. The electronic module includes a motherboard, a multichip module (MCM) mounted to the motherboard, and a circuit unit connected to the MCM. The circuit unit comprises a flexible substrate, instrumentation circuitry mounted on the flexible substrate, and a connector coupled to the flexible substrate. The flexible substrate has signal lines that electrically communicate with the MCM, the instrumentation circuitry, and the connector. A portion of the flexible substrate is located between the MCM and the motherboard and permits electrical communication therebetween. The instrumentation circuitry does not occupy space on the motherboard.

Abstract: A process and electronic assembly for conducting heat from a semiconductor circuit device mounted to a substrate. The substrate is supported by a housing member equipped with a heat-conductive member. A surface of the device opposite the substrate is bonded to the heat-conductive member with a solder joint formed of indium and optionally one or more alloying constituents that increase the melting temperature of the solder joint above that of indium. The housing member, substrate, and device are assembled so that an indium-containing solder material is present between the heat-conductive member and the surface of the device opposite the substrate. The solder material is then reflowed to form the solder joint. The alloying constituent(s) are preferably introduced into the solder joint during reflow.

Abstract: An electronic assembly and/or a mold is constructed to reduce deflection and resultant damage to components and/or an associated printed circuit board of the electronic assembly when the electronic assembly is overmolded.

Abstract: A thermally conductive film is attached to an integrated circuit (IC) wafer through a number of steps. Initially, a thermally conductive film is positioned on a first side of a block. Next, an IC wafer that includes a plurality of chips is positioned with its non-active side in contact with the film. Then, a first surface of an elastomer pad is positioned in contact with an active side of the wafer. Next, a predetermined pressure is applied between a second side of the block that is opposite the first side and a second surface of the elastomer pad that is opposite the first surface. Finally, the film, the block, the wafer and the elastomer pad are heated to a predetermined temperature for a predetermined time while a predetermined pressure is applied to bond the film to the wafer without bonding the film to the block.

Abstract: A package and packaging method that incorporates multiple surface-mounted devices mounted to the package, which in turn can be mounted onto a circuit board. The package generally includes a pair of laminate substrates that together form a chip carrier and input/output (I/O) interface structure for the devices. The devices are mounted to opposite surface of a first of the substrates. The second substrate is attached to the first substrate, and has an interior opening therethrough. The first and second substrates are attached to each other such that devices mounted on one surface of the first substrate are disposed within the interior opening of the second laminate substrate. A mold compound can be applied to underfill and encapsulate the devices mounted to the surfaces of the first substrate.

Abstract: A tin-lead solder alloy containing copper and optionally silver as its alloying constituents. The solder alloy consists essentially of, by weight, about 55% to about 75% tin, about 11% to about 44% lead, up to about 4% silver, nickel, palladium, platinum and/or gold, greater than 1% to about 10% copper, and incidental impurities. The solder alloys contain a small portion of CuSn intermetallic compounds, and exhibit a melting mechanism in which all but the intermetallic compounds melt within a narrow temperature range, though the actual liquidus temperature of the alloys may be considerably higher, such that the alloys can be treated as requiring peak reflow temperatures of about 250° C. or less. The intermetallic compounds precipitate out to form a diffusion barrier that increases the reliability of solder connections formed therewith.

Abstract: An overmolded electronic assembly having an electromagnetic interference shield, in the form of a thin metal film or foil, coupled to the top of or within an overmolded body. The shield effectively reduces the amount of electromagnetic interference (“EMI”) emissions from penetrating within the assembly to the circuit board without substantially increasing the cost of the unit. Thus, an electronic assembly having improved vibration, moisture, and EMI emission resistance is achieved as compared with traditional overmolded or metal assemblies. Further, because the shield can be formed on the electronic assembly in one continuous processing step, a substantial savings in time and cost for the manufacturing process is also realized.

Abstract: An overmolded electronic package includes a circuit-carrying substrate and a connector housing or shroud interconnected via a suitable interconnection arrangement. Some embodiments may include a backplate affixed to the substrate and, in some cases, also to the connector housing or shroud. In some embodiments, the connector housing or shroud may be affixed to the substrate, and in any case the entire subassembly of components is overmolded with a rigidly formable molding compound to bond together all components of the subassembly and form the overmolded electronic package. The subassembly of components with the exception of the backplate may alternatively be overmolded with the molding compound, and a backplate thereafter affixed to the subassembly via a compliant bonding medium.

Abstract: An electronic package and filtered electrical connector assembly includes number of connector pins extending away from a main circuit board having a first ground plane, and an auxiliary circuit board having a second ground plane is positioned over the main circuit board with the connector pins extending therethrough and electrically connected to a corresponding number of capacitors mounted to the auxiliary circuit board. An inductive block and surrounding conductive spacer block are positioned between the main and auxiliary circuit boards with the connector pins extending through the inductive block and with the conductive spacer block electrically contacting the first and second ground planes. A connector shroud surrounds the connector pins extending through auxiliary circuit board, and all components are bonded together via an overmolding process to form the electronic package.

Abstract: A package and packaging method that incorporates multiple surface-mounted devices mounted to the package, which in turn can be mounted onto a circuit board. The package generally includes a pair of laminate substrates that together form a chip carrier and input/output (I/O) interface structure for the devices. The devices are mounted to opposite surfaces of a first of the substrates. The second substrate is attached to the first substrate, and has an interior opening therethrough. The first and second substrates are attached to each other such that devices mounted on one surface of the first substrate are disposed within the interior opening of the second laminate substrate. A mold compound can be applied to underfill and encapsulate the devices mounted to the surfaces of the first substrate.

Abstract: A tin-lead solder alloy containing copper and optionally silver as its alloying constituents. The solder alloy consists essentially of, by weight, about 55% to about 75% tin, about 11% to about 44% lead, up to about 4% silver, nickel, palladium, platinum and/or gold, greater than 1% to about 10% copper, and incidental impurities. The solder alloys contain a small portion of CuSn intermetallic compounds, and exhibit a melting mechanism in which all but the intermetallic compounds melt within a narrow temperature range, though the actual liquidus temperature of the alloys may be considerably higher, such that the alloys can be treated as requiring peak reflow temperatures of about 250° C. or less. The intermetallic compounds precipitate out to form a diffusion barrier that increases the reliability of solder connections formed therewith.

Abstract: An overmolded circuit board assembly and a method for forming the assembly. The assembly and method entail overmolding both surfaces of a circuit board and underfilling at least one surface-mount circuit device attached to at least one surface of the board with solder bump connections, with the result that the circuit device is spaced above the surface of the circuit board so as to define a gap therebetween. A cavity, such as a blind hole or closed through-hole, is defined in the surface of the circuit board beneath the circuit device and communicates with the gap but is closed off from the opposite surface of the circuit board. Air that is trapped in the gap by a molding material during the overmolding/underfilling process is collected and compressed within the cavity, yielding a void-free underfill between the circuit board and circuit device.

Abstract: An overmolded electronic assembly having an electromagnetic interference shield, in the form of a thin metal film or foil, coupled to the top of or within an overmolded body. The shield effectively reduces the amount of electromagnetic interference (“EMI”) emissions from penetrating within the assembly to the circuit board without substantially increasing the cost of the unit. Thus, an electronic assembly having improved vibration, moisture, and EMI emission resistance is achieved as compared with traditional overmolded or metal assemblies. Further, because the shield can be formed on the electronic assembly in one continuous processing step, a substantial savings in time and cost for the manufacturing process is also realized.

Abstract: A solder alloy containing indium, lead, silver and copper as its alloying constituents, and a soldering process employing the solder alloy. The solder alloy consists essentially of, by weight, about 50% to about 65% indium, about 0.5% to about 3.0% silver, up to about 3.0% copper, the balance lead and incidental impurities. The alloy preferably has a solidus temperature in a range of about 173° C. to about 178° C., and a liquidus temperature in a range of about 187° C. to about 196° C. As such, the alloy can be used in a reflow process with a peak reflow temperature of about 220° C. to about 240° C., and is therefore compatible with most circuit components and can be simultaneously reflowed with 63Sn-37Pb solder.

Abstract: A solder alloy containing indium, lead, silver and copper as its alloying constituents, and a soldering process employing the solder alloy. The solder alloy consists essentially of, by weight, about 50% to about 65% indium, about 0.5% to about 3.0% silver, up to about 3.0% copper, the balance lead and incidental impurities. The alloy preferably has a solidus temperature in a range of about 173° C. to about 178° C., and a liquidus temperature in a range of about 187° C. to about 196° C. As such, the alloy can be used in a reflow process with a peak reflow temperature of about 220° C. to about 240° C., and is therefore compatible with most circuit components and can be simultaneously reflowed with 63Sn-37Pb solder.

Abstract: An integrated circuit assembly 10 is provided, including a substrate 14 having at least one substrate contact surface 18, an integrated circuit device 12 having at least one first contact surface 16, and a bar bond element 22. The bar bond element 22 provides communication between the at least one substrate contact surface 18 and the at least one first contact surface 16. The bar bond element 22 includes a conductive plate element 23 having an integrated circuit foot portion 24, a substrate foot portion 26 and a strain relief loop 46 positioned between the integrated circuit foot portion 24 and the substrate foot portion 26.

Abstract: A solder alloy containing indium, lead, silver and copper as its alloying constituents, and a soldering process employing the solder alloy. The solder alloy consists essentially of, by weight, about 50% to about 65% indium, about 0.5% to about 3.0% silver, up to about 3.0% copper, the balance lead and incidental impurities. The alloy preferably has a solidus temperature in a range of about 173° C. to about 178° C., and a liquidus temperature in a range of about 187° C. to about 196° C. As such, the alloy can be used in a reflow process with a peak reflow temperature of about 220° C. to about 240° C., and is therefore compatible with most circuit components and can be simultaneously reflowed with 63Sn-37Pb solder.

Abstract: An overmolded circuit board assembly and a method for forming the assembly. The assembly and method entail overmolding both surfaces of a circuit board and underfilling at least one surface-mount circuit device attached to at least one surface of the board with solder bump connections, with the result that the circuit device is spaced above the surface of the circuit board so as to define a gap therebetween. A cavity, such as a blind hole or closed through-hole, is defined in the surface of the circuit board beneath the circuit device and communicates with the gap but is closed off from the opposite surface of the circuit board. Air that is trapped in the gap by a molding material during the overmolding/underfilling process is collected and compressed within the cavity, yielding a void-free underfill between the circuit board and circuit device.