The present disclosure related to a flexible electronic substrate assembly and a method and system of processing solder paste onto an electrical substrate. The assembly includes a flexible substrate having a solderable medium provided along the flexible substrate. A pattern of solder paste may be cured to a portion of the solderable medium. The solderable medium may be a generally continuous construction or a patterned construction relative to the flexible substrate. The substrate may be unwound from a roll of substrate material before solder paste is deposited thereon. The flexible electric substrate assembly may be formed though a roll to roll process. Infrared heat may be applied to the substrate with the solder paste deposit as the substrate is traveling along the process direction to reflow the solder paste as the substrate is traveling along the process direction at a high rate of speed.

According to an embodiment of the present disclosure, a method for manufacturing an integrated circuit (IC) device may include mounting an IC chip onto a center support structure of a leadframe. The leadframe may include: a plurality of pins extending from the center support structure; a groove running perpendicular to the individual pins of the plurality of pins around the center support structure; and a bar connecting the plurality of pins remote from the center support structure. The method may further include: bonding the IC chip to at least some of the plurality of pins; encapsulating the leadframe and bonded IC chip, including filling the groove with encapsulation compound; removing the encapsulation compound from the groove, thereby exposing at least a portion of the individual pins of the plurality of pins; plating the exposed portion of the plurality of pins; and cutting the IC package free from the bar by sawing through the encapsulated lead frame along the groove using a first saw width less than a width of the groove.

The present disclosure is related to a power module includes a first printed circuit board (PCB), a second PCB, a magnetic component and a connecting component. A secondary side switch set and a winding are disposed on the first PCB, respectively. A primary side switch set is disposed on the second PCB adjacent to the first PCB. A magnetic component includes an upper magnetic cover disposed on the first side of the first PCB; a lower magnetic cover disposed between the first PCB and the second PCB; and a lateral column located between the two magnetic covers. The lateral column passes through the first PCB, and is fastened with the two magnetic covers. The magnetic component and the winding collaboratively form a transformer. The connecting component is disposed between the two PCBs to connect the corresponding potential points of the two PCBs.

A solder composition of the invention includes: a flux composition containing a component (A) in a form of a rosin-based resin, a component (B) in a form of an activator, a component (C) in a form of a solvent and a component (D) in a form of a thixotropic agent; and a component (E) in a form of a solder powder. The component (C) in a form of the solvent contains a component (C1) in a form of a isobornyl cyclohexanol and a component (C2) in a form of a solvent whose viscosity at 20 degrees C. is 10 mPa.Math.s or less and whose boiling point ranges from 220 degrees C. to 245 degrees C.

A metal wiring bonding structure 100 comprises contacts 753 of connection FPC 75 and heater lands 46 of a sheet heater 30 to be bonded by a solder bonding member 766. A connection FPC 75 includes contact opposed lands 754 famed of metal and disposed at positions respectively opposed to the plurality of contacts 753 on a surface of a support layer 751 opposite from a surface on which metal wires 750 are provided, and through holes 755 penetrating the contact opposed lands 754, the support layer 751, and contacts 753. Solder bonding members 756 cover surfaces of contact opposed lands 754 and are filled inside through holes 755 and in a bonding space C.

The present disclosure describes light systems in which the intensity of base color LEDs configured to emit light within a target color region is increased using additional white LEDs and the emitted light is filtered so that a dominant portion of light passing through the filter at a particular viewing angle is within the target color region. The present disclosure also describes methods for forming a printed circuit board with an integral heat sink arrangement by depositing additional solder on solder pads that are not used to connect electronic components so that the additional solder acts as a heat sink.

Methods and apparatus for joining a chip with a substrate. The chip is moved by with a pick-and-place machine from a first location to a second location proximate to the substrate over a first time. In response to moving the chip in a motion path from the first location to the second location, a plurality of solder bumps carried on the chip are liquefied over a second time that is less than the first time. While the solder bumps are liquefied, the chip is placed by the pick-and-place machine onto the substrate.

A soldering apparatus includes a reflow oven, a transmission mechanism, and a controlling unit. The reflow oven includes an inlet and an output mechanism. The output mechanism includes two guide rails and two link belts. An end of a first guide rail has a first alignment structure. The two link belts are movably disposed on the guide rails for outputting a printed wiring board. A distance between the guide rails is previously adjusted to be equal to a width of the printed wiring board. The transmission mechanism includes two tracks and two conveyor belts. An end of a first track has a second alignment structure. The two conveyor belts are movably disposed on the two tracks for transporting the printed wiring board. The controlling unit controls a movement of the first track, so that the first alignment structure and the second alignment structure are automatically aligned with each other.

Embodiments of a thermal compression bonding (TCB) process cooling manifold, a TCB process system, and a method for TCB using the cooling manifold are disclosed. In some embodiments, the cooling manifold comprises a pre-mixing chamber that is separated from a mixing chamber by a baffle. The baffle may comprise at least one concentric pattern formed through the baffle such that the primary cooling fluid in the pre-mixing chamber is substantially evenly distributed to the mixing chamber. The pre-mixing chamber may be coupled to a source of primary cooling fluid. The mixing chamber may have an input configured to accept the primary cooling fluid and an output to output the primary cooling fluid.

An electronic component mounting structure includes a terminal of an electronic component package and a chip heat radiating member. The terminal is soldered on a land of an electronic substrate and the chip heat radiating member is soldered on a back surface of the package. The chip heat radiating member is covered by a packaging resin. The metallic heat radiating pattern integrally includes a pattern extension part that is protruded from the package, such that at least a part of the metallic heat radiating pattern in formed to be larger than the package. The pattern extension part guides excessive solder to outside of the package.