A fluxing-encapsulant material and method of use thereof in a thermal compression bonding (TCB) process is described. In an embodiment, the TCB process includes ramping the bond head to 250 C.-300 C. at a ramp rate of 50 C./second-100 C./second. In an embodiment, the fluxing-encapsulant material comprising one or more epoxy resins having an epoxy equivalent weight (EEW) of 150-1,000, a curing agent, and a fluxing agent having a mono-carboxylic acid or di-carboxylic acid and a pKa of 4-5.

In an embodiment, there is provided a method of creating a package, the method comprising: providing an initial substrate, wherein the initial substrate comprises a carrier foil, a functional copper foil, and an interface release layer between the carrier foil and the functional copper foil; building up copper portions on the functional copper foil; attaching a chip to a first copper portion; coupling the chip to a second copper portion; encapsulating at least the chip and the copper portions with a mold; and removing the carrier foil and interface release layer.

The device bends readily and safely without a sealing resin peeling off or a breakage in a wire. In an LED columnar light emitting device 1 in which a plurality of two conductive regions 2 and 3 corresponding to the polarities are provided in the columnar direction on a film wiring board, each light emitting element is connected to and installed on the plurality of two conductive regions 2 and 3, and each LED chip 6, as each light emitting element, is sealed above with a transparent sealing resin 8, notch sections 9 and 9A are formed on both outer sides of two plated lines 4 as opening sections between the two conductive regions 2 and 3 and another two conductive regions 2 and 3 adjacent thereto in the columnar direction.

A method of manufacturing a flexible electronics module includes mounting at least two functional components onto a flexible substrate, forming stretchable electrical interconnects configured to provide connection between the two functional components, and cutting shapes into the flexible substrate to increase an ability of the flexible substrate to stretch and flex, wherein the electrical interconnects to the functional components are placed to avoid the shapes.

The present invention discloses an electronic package structure. The body has a top surface with a cavity thereon, the first conductive element is disposed in the cavity, and the second conductive element is disposed in the body. The first external electrode electrically connected to the first conductive element and the second external electrode electrically connected to the second conductive element are both disposed on the top surface of the body or a first surface formed by the top surface of the encapsulation compound and the exposed portions of the top surface of the body which are not covered by the encapsulation compound.

When forming a module 100 having a configuration in which a column-shaped connection terminal 11, which forms an interlayer connection conductor, and an electronic component 102 are mounted on a wiring substrate 101 and sealed with a resin, the column-shaped connection terminal 11 which has a substantially T-shaped cross section and in which a first end portion has a larger diameter than a second end portion is prepared (the preparation step), an electronic component 102 is mounted on one main surface of the wiring substrate 101 and the connection terminal 11 is mounted on the one main surface in such a manner that the second end portion of the connection terminal 11 having a smaller diameter is connected to the wiring substrate 101 (the mounting step), and the electronic component 102 and the connection terminal 11 are sealed with a resin layer 103 (the sealing step).

A multiple-ply solid state light fixture is disclosed. A panelized, solid state light fixture includes combined layers of material chemically bonded together without a traditional mechanical housing and with relatively few or no fasteners. In example embodiments, the solid state light fixture includes an LED mounting substrate, a thermal material on a non-LED side of the LED mounting substrate, and an optical material on the LED side of the LED mounting substrate. A plurality of LEDs are disposed or mounted, with or without additional packaging, on the LED side of the LED mounting substrate. A chemical bond is created between the substrate and the other layers. This chemical bond can be created, for example, through use of applied fluid or gelatinous compounds that are then solidified, or through the use of adhesives.

A method of manufacturing package structure includes following steps. An insulating composite layer is formed on a metal layer of a carrier board. A chip packaging module including a sealant and a first chip embedded therein is disposed on the insulating composite layer, in which the first chip has a plurality of conductive pads. A first circuit layer module including a dielectric layer and a circuit layer is formed on the chip packaging module, in which the circuit layer is on the dielectric layer and electrically connected to the conductive pads through a conductive vias in the dielectric layer. A second chip is disposed on the first circuit layer module. A second circuit layer module is formed on the first circuit layer module and the second chip. A protecting layer is formed on the second circuit layer module.