A semiconductor package includes a substrate body made of an insulating material and having a frame shape with a through hole; and a heat-dissipating member made of a metallic material and having a top face serving as an element-mounting surface, the element-mounting surface being positioned in the through hole. A back face of the substrate body and a front face of the heat-dissipating member are joined to each other with a joining agent, the back face being oriented downward, the front face being oriented upward. The substrate body includes a first riser portion extending downward from the back face. The heat-dissipating member includes a second riser portion extending upward from the front face. The joining agent is placed in a space enclosed by the back face, the first riser portion, the front face, and the second riser portion.

A deep ultraviolet (DUV) light-emitting diode (LED) module structure contains: a holder configured to accommodate a substrate. The holder including a receiving cup mounted therein and a transparent layer mounted on a top of the receiving cup. The holder includes a DUV LED chip adhered on the substrate, and the holder, the substrate, and the DUV LED chip are connected and packaged. The substrate is electrically connected with a drive circuit, and the drive circuit is configured to turn on/off the DUV LED chip. Thereby, the DUV LED module structure enhances DUV radiation intensity, reduces a loss of optical path, and slows down deterioration because of DUV irradiation.

A method of manufacturing a display module which is able to present a split-screen display without a black line prominent at the boundary includes: providing a first circuit substrate including a plurality of first pads, providing a second circuit substrate including a plurality of second pads; bonding the first circuit substrate and the second circuit sub state onto a surface of a heat dissipation plate through a first heat conductive adhesive; and mounting a plurality of light emitting diodes onto the first conductive wiring layer and the third conductive wiring layer, where one light emitting diodes is electrically connected to two first pad, one light emitting diode is electrically connected to one first pad and one second pad, and one light emitting diode is electrically connected to two second pads. A display module including light emitting diodes is also disclosed.

A circuit part is provided that provides both high heat dissipation and high adhesion of its circuit wiring. A circuit part includes: a metal member; an insulating resin layer located on the metal member; circuit wiring including a plating film located on the insulating resin layer; and a mounted component mounted on the circuit wiring and electrically connected to the circuit wiring, wherein a plurality of non-penetrating holes are provided in a wiring region, the non-penetrating holes being filled with the plating film, the wiring region being a portion of the resin-layer surface on which the circuit wiring is located, and the ratio of the depth d of the non-penetrating holes to the width D of the non-penetrating holes, d/D, is 0.5 to 5.

A light emitting device is provided that includes an integral heat dissipation element. This heat dissipation element is included in the leadframe that is used to facilitate fabrication of the light emitting device, to provide a single common substrate that forms both the heat dissipation element and the conductive elements for coupling the light emitting device to external sources of power. The heat dissipation element may extend beyond the protective structure that surrounds the light emitting element to facilitate heat dissipation to the surrounding medium.

An LED package is described that acts as a sub-mount between a printed circuit board and a diode. The sub-mount includes a laminate to thermally isolate the diode, for example an LED, from the PCB while providing a thermal heat dissipative sink for the diode.

A light emitting device includes: a substrate; one or more LED (light emitting diode) elements mounted on a substrate; and a radiator unit made of metal paste and arranged on a rear surface opposite to a principal surface on which the one or more LED elements are mounted. The height Ta of the radiator unit from a rear surface is less than thickness Tb of substrate.

A flexible graphite sheet support structure forms a thermal management arrangement for device having a heat source. The flexible graphite sheet support structure includes first and second spaced apart support members and a flexible graphite sheet secured to the spaced apart support members forming a free standing flex accommodating section that spans between them. Curve retention members having convex curved surfaces are used to keep the flex accommodating section in a bell shaped curve while preventing the flexible graphite sheet from exceeding a minimum bend radius. The thermal management arrangement formed by the flexible graphite sheet support structure enables the flexible graphite sheet to move heat from one support structure to the other while reducing the transmission of vibration between them and allowing relative movement between the spaced apart support structures.

A method to fill the flowable material into the semiconductor assembly module gap regions is described. In an embodiment, multiple semiconductor units are formed on the substrate to create an array module; the array module is attached to a backplane having circuitry to form the semiconductor assembly module in which multiple gap regions are formed inside the semiconductor assembly module and edge gap regions are formed surround an edge of the assembly module; The flowable material is forced inside the gap regions by performing the high acting pressure environment and then cured to be a stable solid to form a robustness structure. A semiconductor convert module is formed by removing the substrate utilizing a substrate removal process. A semiconductor driving module is formed by utilizing a connecting layer on the semiconductor convert module. In one embodiment, a vertical light emitting diode semiconductor driving module is formed to light up the vertical LED array. In another one embodiment, multiple color emissive light emitting diodes semiconductor driving module is formed to display color images. In another embodiment, multiple patterns of semiconductor units having multiple functions semiconductor driving module is formed to provide multiple functions for desire application.

A wavelength conversion member includes: a phosphor; a metal joining layer provided on a bottom surface and a side surface of the phosphor; a metal heat-dissipating holding unit including a recess that covers the bottom surface and at least a portion of the side surface of the phosphor and that accommodates the phosphor so that the phosphor is embedded in the recess; and a metal porous joining material provided between the metal joining layer and the metal heat-dissipating holding unit.