A light emitting device package including a package body including a first cavity and a second cavity, a pad disposed on a bottom surface of the first cavity, a light emitting device disposed on the second cavity electrically connected to the pad, a heat dissipation member inserted into the package body, the heat dissipation member including a body and expanded portions disposed at a partial edge region of the body and electrode patterns disposed at the package body, wherein the package body has an upper portion and a lower portion disposed under the upper portion, wherein the first cavity including side surfaces and a bottom surface, wherein the second cavity provided in the bottom surface of the first cavity.

A thermally conductive sheet contains a matrix resin and thermally conductive particles. The content of the thermally conductive particles is 200 parts by volume or more with respect to 100 parts by volume of the matrix resin component. A polymer viscosity of the matrix resin component after a crosslinking reaction in the absence of the thermally conductive particles is 500 Pa.Math.s or less at 25° C. A thermal conductivity of the thermally conductive sheet is 2.0 W/m.Math.K or more. When the thermally conductive sheet with an initial thickness of 1.5 mm is compressed at a compression rate of 5.0 mm/min to measure a 50% compressive load value, the maximum load value is 100 kPa or more and the load value after 1 minute is more than 0 kPa and 100 kPa or less. With this configuration, the thermally conductive sheet has a high thermal conductivity, a low steady load value, and flexibility.

An optoelectronic semiconductor component includes a carrier having a carrier top side and an opposing carrier underside, wherein the carrier top sides each have a larger area than the associated carrier undersides, the carrier parts fixedly connect to one another via at least one potting body and the potting body together with the carrier parts represents a bearing component of the semiconductor component so that all carrier undersides end flush with the potting body, the light-emitting semiconductor chips electrically connect in series, the metal layer on the carrier top side is structured into conductor tracks and into electrical connection surfaces, and the electrical connection surfaces on the carrier top side are electrically insulated from the associated carrier underside so that the carrier underside of the carrier part the semiconductor chips are arranged on is potential-free and is completely covered with the metal layer.

A composite substrate includes a submount substrate of an alternating pattern of electrically insulative portions, pieces, layers or segments and electrically conductive portions, pieces, layers or segments, and a shaft, back or plate for supporting the alternating pattern of electrically insulative portions and electrically conductive portions. An active device having a P-N junction can be mounted on the submount substrate. The electrically insulative portions, pieces, layers or segments can be formed from diamond while the electrically conductive portions, pieces, layers or segments can be formed from a metal or metal alloy.

The present invention provides an LED lamp heat sink which has excellent thermal conductivity and moldability, is light in weight, and can be produced at low cost. The LED lamp heat sink is partially or wholly made of a thermally conductive resin composition and cools an LED module. The thermally conductive resin composition contains at least: 10 to 50 wt. % of thermoplastic polyester resin (A) having a number average molecular weight of 12,000 to 70,000; 10 to 50 wt. % of polyester-polyether copolymer (B); and 40 to 70 wt. % of scale-like graphite (C) having a fixed carbon content of 98 wt. % or more and an aspect ratio of 21 or more. Specific gravity of the thermally conductive resin composition is 1.7 to 2.0. Heat conductivity of the thermally conductive resin composition in a surface direction is 15 W/(m.Math.K) or more.

A light emitter device component containing one or more light emitter devices, such as light emitting diodes (LEDs) or LED chips, can include a body that can be ceramic and have a top surface, one or more light emitting devices mounted directly or indirectly on the top surface, and one or more electrical components mounted on the top surface and electrically coupled to the one or more light emitting devices. At least a portion of the top surface of the body to which the light emitting devices are mounted can be modified to have a reduced porosity compared to an as-fired ceramic body. Such components can result in improved adhesion strength and thermal management of the light emitting devices.

Provided is a substrate for a light emitting device having high reflectivity, high heat radiating properties, dielectric strength voltage properties, long-term reliability including heat resistance and light resistance, and excellent mass productivity. A substrate (20) for a light emitting device includes: a first insulating layer (11) having thermal conductivity which is formed on a surface of one side of a metal base (2); a wiring pattern (3) which is formed on the first insulating layer (11); and a second insulating layer (12) having light reflectivity which is formed on the first insulating layer (11) and on some parts of the wiring pattern (3), so that some parts of the wiring pattern (3) are exposed, in which the first insulating layer (11) is a layer of ceramic formed by thermal spraying.

A method of making a LED light bulb with the Graphene filament contains steps of: A. providing a flexible substrate, wherein the flexible substrate is flexible printed circuit board (PCB); B. coating graphene-based heat dissipation ink on a back side of the flexible substrate; C. cutting the printed circuit board (PCB) on which a graphene-based heat dissipation film is coated to form plural Graphene filaments; D. fixing the plural Graphene filaments into a light bulb. The flexible substrate has copper lines formed on both sides thereof for electronic circuits and heat conduction, and LED chips are mounted on a front side of the flexible substrate. The graphene-based heat dissipation ink is coated on the back side of the flexible substrate before or after LED chips/phosphor molding and then is dried. In addition, the Graphene filaments are fixed in a bended or arched position.

A three-dimensional molded circuit component, includes: a base member which includes a metal part and a resin part; a circuit pattern which is formed on the resin part; and a mounted component which is mounted on the base member, and is electrically connected to the circuit pattern. The resin part includes a resin thin film as a portion thereof, which includes a thermoplastic resin, of which a thickness is in the range of 0.01 mm to 0.5 mm, and which is formed on the metal part. The mounted component is arranged on the metal part via the resin thin film.

A semiconductor element package includes: a semiconductor element arranged above a first substrate; first and second electrodes arranged above the first substrate and electrically connected to the semiconductor element; a housing which is arranged above the first substrate and arranged around the semiconductor element, and which has a stepped portion in the upper area thereof; a diffusion part arranged on the stepped portion of the housing and arranged above the semiconductor element; and a plurality of via holes penetrating the first substrate and the housing.