Abstract: A laminated light-emitting diode display device and a manufacturing method thereof are described. The laminated light-emitting diode display device has an insulator, a circuitry device placed on the insulator and having of a plurality of circuits interconnected with each other, and a plurality of SMT-type light-emitting diodes electrically connected to the circuits of the circuitry unit.

Abstract: A water-cooling heat dissipation device adopted for a lighting module that includes a plurality of LEDs modulized together, and includes a heat dissipation plate, at least one curved canal recessed inside the heat dissipation plate, at least one inlet formed on one of the sides of the heat dissipation plate selectively, and at least one outlet formed on one of the sides of the heat dissipation plate selectively. The curved canal created as a part of the heat dissipation plate runs laterally and includes at least one bending portion arranged thereon. The inlet and the outlet communicate with the bending portion and a free end of the curved canal in alternative manners, respectively. The lighting module contacts a top of the heat dissipation device directly.

Abstract: Multiple LED matrix array circuit boards are pieced together a form a display panel. L-shape brackets are mounted on the bottom sides of the circuit boards and aligned with the butting edges of the circuit boards. The vertical butting walls are pressed together by clamps. A set screw is inserted in one jaw of the clamp to tighten the pressure between butting edges of the circuit boards. Another set screw is inserted on top of the clamp to align the adjacent boards vertically.

Abstract: A wafer-level electro-optical semiconductor fabrication mechanism and method for the same which improves upon traditional electro-optical semiconductor grain packaging methods. The present invention electrically connects semiconductor grains to the grains on a top surface of a wafer. this is done by either screen-printing or steel board-printing solder or silver paste onto the wafer. After that, the wafer is processed using the following steps: processing the devices, bonding with wire, packaging the wafer and finally cutting the wafer. Using this method raises the production yield while production times and costs are reduced. The wafer-level electro-optical semiconductor fabrication mechanism comprises: a wafer, an electro-optical semiconductor grain and conductive materials.

Abstract: An LED package structure and a method for making the same are described. The LED package structure has at least one LED die, at least one metallic frame relating to the LED die, and an insulative body packaging the LED die and the metallic frame. The metallic frame has a first contact corresponding to the LED die and a second contact being relative to the first contact. The first and the second contacts inside the insulative body are electrically isolated from each other. The first contact has at least one recess around the LED die, and the second contact has at least one groove formed thereon.

Abstract: A wafer-level electro-optical semiconductor manufacture fabrication method improves upon traditional electro-optical semiconductor grain packaging methods. The present invention electrically connects semiconductor grains to the grains on a top surface of a wafer. This is done by either screen-printing or steel board-printing solder or silver paste onto the wafer. After that, the wafer is processed using the following steps: processing the devices, bonding with wire, packaging the wafer and finally cutting the wafer. Using this method raises the production yield while production times and costs are reduced. The wafer-level electro-optical semiconductor fabrication mechanism comprises: a wafer, an electro-optical semiconductor grain and conductive materials.

Abstract: A multi-wavelength white light emitting diode uses a UV light emitting diode chip and a blue light emitting diode chip to excite a red phosphor and a green phosphor and generates a white light emitting diode having good color rendering. The multi-wavelength white light emitting diode uses a UV light emitting diode chip that emits light having a wavelength of between 350˜430 nm to excite a red phosphor to emit red light having a wavelength of between 600˜700 nm. The present invention then uses a blue light emitting diode chip that emits light having a wavelength between of 400˜500 nm to emit blue light and uses the blue light emitting diode chip to excite a green phosphor to emit green light having a wavelength of between 490˜560 nm. Mixing the red light, the blue light and the green light forms a white light.

Abstract: A light module includes a lighting unit, a heat-dissipation plate and an insulative plate. The lighting unit has a leading contact. The heat-dissipation plate contacts the lighting module closely and has a channel corresponding to the leading contact. The insulative plate is disposed under the heat-dissipation plate, and has a predetermined conductive pattern arranged thereon and a through hole corresponding to the channel. The leading contact of the lighting unit penetrates through the channel of the heat-dissipation plate and the through hole of the insulative plate to electrically connect with the predetermined conductive pattern of the insulative plate.

Abstract: A backlight module arranged under a flat display includes a printed circuit board being parallel to the flat display and including a plurality of LEDs, a reflection portion being a reflection wall bent from a fringe of the LEDs to extend over the LEDs, and a guide light plate being parallel to the printed circuit board. The reflection portion includes an orientation wall parallel to the reflection wall and an outlet with a direction parallel to the printed circuit board. The guide light plate has an end connecting inside the outlet of the reflection portion, a light delivering surface adjacent to the flat display, and a reflection surface arranged at a bottom thereof.

Abstract: An LED package structure and a method for making the same are described. The LED package structure has at least one LED die, at least one metallic frame relating to the LED die, and an insulative body packaging the LED die and the metallic frame. The metallic frame has a first contact corresponding to the LED die and a second contact being relative to the first contact. The first and the second contacts inside the insulative body are electrically isolated from each other. The first contact has at least one recess around the LED die, and the second contact has at least one groove formed thereon.

Abstract: A wafer-level electro-optical semiconductor fabrication mechanism and method for the same which improves upon traditional electro-optical semiconductor grain packaging methods. The present invention electrically connects semiconductor grains to the grains on a top surface of a wafer. this is done by either screen-printing or steel board-printing solder or silver paste onto the wafer. After that, the wafer is processed using the following steps: processing the devices, bonding with wire, packaging the wafer and finally cutting the wafer. Using this method raises the production yield while production times and costs are reduced. The wafer-level electro-optical semiconductor fabrication mechanism comprises: a wafer, an electro-optical semiconductor grain and conductive materials.

Abstract: An LED packaging structure has a substrate having two holes formed thereon. One of two conductive elements extends through the two holes to connect electrically to a conductive pad and a first electrode pad on the upper and lower surfaces of the substrate and the other of the two conductive elements extends through the holes to connect to the conductive strip and the second electrode pad on the upper and lower surfaces the substrate. A light-emitting chip electrically connects to the conductive pad and the conductive strip. The light-emitting chip is encapsulated by a protection colloid on the substrate, so as to make LED packaging structure easy to fabricate and avoid the short circuits of adjacent LED packaging structures due to contact between conductor materials therebetween.

Abstract: A method of manufacturing a substrate structure includes the steps of: (1) providing a metal substrate having a metal portion; (2) chemically etching a plurality of trenches in the metal substrate; (3) applying a polymer composite material into the trenches to form a substrate having a polymer composite portion abutted to the metal portion; (4) polishing a surface of the substrate to make a height of the polymer composite portion equal to that of the metal portion; (5) forming a covering material on the surface of the substrate; and (6) cutting the substrate via the polymer composite portion for decreasing cutting bur produced on the metal portion. Furthermore, the method is provided for combining the metal substrate and the polymer composite material, thereby to increase cutting precision and strength of the substrate structure.

Abstract: A package structure for an optical-electrical semiconductor is described. The package structure has a thermal conductive structure for heat transfer and is integrally formed in one piece to improve the structural strength thereof, while the thermal conductive structure prevent over-heating of the LED device for greater longevity. The package structure reduces the failure rate in production and has improved quality. When the present invention is applied in light-emitting diode packages, the special requirement can be reached and has better properties than the prior art.

Abstract: An LED lamp uses a plurality of LEDs as a light source. The LED lamp has a casing, a conduction layer, a PCB, a plurality of LED and a drive electronics. The conduction layer is placed in an inner of the casing. The conduction layer is metal, copper or aluminum, or nonmetal, silica gel or mica, for conducting the heat of the PCB caused by the current heating effects. The PCB placed on an upper surface of the conduction layer is for mounting the LED. Each LED is electrically connected to the PCB by way of shunt winding or in series for providing a light source. The drive electronics is electrically connected to the PCB for driving color rendering.

Abstract: A semiconductor substrate structure with a highly heat-conductive advantage increases packaging good rate and quality. Using semiconductor chip packaging, an electronic chip is easily made highly heat-conductive, and compared with the prior art, the present invention has superior good rate for substrate structure. The improved heat-conductive structure avoids the semiconductor chip overheating and affects the life of electronic device by directly connecting the chip to the heat-conductive base plate.

Abstract: A mixing light board which shows specific pattern is described. The present invention have some advantages, including simple construction, easy production, thinness and cheapness. The mixing light board has a body with a front surface and a back surface. A plurality of conducting material is set on the front surface of the body. A plurality of LEDs is mounted by SMT on the front surface of the body, and the plurality of LEDs is arranged to form a specific pattern. The mixing light board can be made to fit demands.

Abstract: A laminated light-emitting diode display device and a manufacturing method thereof are described. The laminated light-emitting diode display device has an insulator, a circuitry device placed on the insulator and having of a plurality of circuits interconnected with each other, and a plurality of SMT-type light-emitting diodes electrically connected to the circuits of the circuitry unit.

Abstract: A semiconductor substrate structure includes a substrate having a trench formed thereon, a polymer composite material supplied into the trench and an electroplate conductive layer formed on the substrate. Further, a semiconductor substrate processing method includes the steps of: providing a substrate forming a trench thereon, supplying a polymer composite material into the trench, polishing a surface of the substrate and forming a covering material on the surface of the substrate. Therefore, the method is provided for combining the polymer composite material into the substrate, thereby to raise cutting precision and strength of the semiconductor substrate structure.

Abstract: A semiconductor substrate structure includes a substrate having a trench formed thereon, a polymer composite material supplied into the trench and an electroplate conductive layer formed on the substrate. Further, a semiconductor substrate processing method includes the steps of: providing a substrate forming a trench thereon, supplying a polymer composite material into the trench, polishing a surface of the substrate and forming a covering material on the surface of the substrate. Therefore, the method is provided for combining the polymer composite material into the substrate, thereby to raise cutting precision and strength of the semiconductor substrate structure.