Abstract: A flip chip type LED lighting device manufacturing method includes the step of providing a strip, the step of providing a submount, the step of forming a metal bonding layer on the strip or submount, the step of bonding the submount to the strip, and the step of cutting the structure thus obtained into individual flip chip type LED lighting devices.

Abstract: A flip chip type LED lighting device manufacturing method includes the step of providing a strip, the step of providing a submount, the step of forming a metal bonding layer on the strip or submount, the step of bonding the submount to the strip, and the step of cutting the structure thus obtained into individual flip chip type LED lighting devices.

Abstract: A flip chip type LED lighting device manufacturing method includes the step of providing a strip, the step of providing a submount, the step of forming a metal bonding layer on the strip or submount, the step of bonding the submount to the strip, and the step of cutting the structure thus obtained into individual flip chip type LED lighting devices.

Abstract: The invention provides a packaged system that is suitable for a LED package of high power. The packaged system further includes a heat-conducting device surrounded by at least one heat-dissipating fin to effectively dissipate the heat generated by the high power LED package. The packaged system with high efficiency of heat dissipation can be incorporated into various projecting illuminating equipments, such as a flashlight or floodlight, by simply installing the present invention into a housing and providing power connection thereto.

Abstract: The invention provides a semiconductor light-emitting device package structure. The semiconductor light-emitting device package structure includes a substrate, N sub-mounts, and N semiconductor light-emitting die modules, wherein N is a positive integer lager than or equal to 1. Each of the sub-mounts is embedded on the substrate and exposed partially. Each of the semiconductor light-emitting die modules is mounted on the exposed surface of one of the sub-mounts.

Abstract: The invention provides a system-in-package, high power, and highly efficient light-emitting diode lamp. The light-emitting diode lamp, according to the invention, includes a light-guiding device. At least one end of two ends of the light-guiding device, the light, converted by a diode light-emitting device from an electric energy, is emitted into, and then is guided by the light-guiding device outside. The heat generated during light-emitting of the diode light-emitting is conducted by a heat-conducting device from a flat portion thereof to at least one heat-dissipating fin and further dissipated by the at least one heat-dissipating fin.

Abstract: Disclosed is a light source, which includes a light-permeable casing, a thermoconductor, which is mounted inside the casing and has a flat end portion, a plurality of radiation fins fastened to the periphery of the thermoconductor inside the casing, a light source formed of an array of LEDs and installed in the flat end portion of the thermoconductor inside the casing, and a power unit mounted inside the casing to provide the light source with the necessary working voltage.

Abstract: The invention relates to a light-emitting diode cluster lamp. The light-emitting diode cluster lamp includes a plurality of light-emitting diode lamp packages, a control circuit, and a casing. Each of the light-emitting diode lamp packages includes a heat-conducting/dissipating module and a light-emitting diode module. The control circuit module is used for controlling the light-emitting diode lamp packages. The casing is adapted to accommodate the light-emitting diode lamp packages and the control circuit module. When the light-emitting diode cluster lamp is connected to a power source, the control circuit module selectively makes the light-emitting diode modules emit light. The heat generated during the light emission of each of the light-emitting diode modules is conducted and dissipated by the corresponding heat-conducting/dissipating module of each of the light-emitting diode modules.

Abstract: A light source assembly includes a vapor chamber, which has an electrical circuit installed in the top surface, an insulation layer covered in between the top surface of the vapor chamber and the electrical circuit, and light emitting diodes installed in the top surface directly of the vapor chamber and electrically connected to the electrical circuit for producing light upon connection of electricity to the electrode circuit means and the vapor chamber, and a heat sink installed in the bottom surface of the vapor chamber for dissipation of heat energy from the vapor chamber into outside open air.