An electronic device includes a heat dissipation structure. The heat dissipation structure comprises a flexible substrate, a graphite sheet, and a heat insulating material. The flexible substrate comprises a first surface and a second surface facing away from the first surface. The flexible substrate is disposed on the graphite sheet, and the second surface faces the graphite sheet. At least one containing cavity is formed between the flexible substrate and the graphite sheet. The heat insulating material is filled in the containing cavity. A cover plate is disposed on the first surface. At least one groove is formed on the flexible substrate from the first surface to the second surface. The groove is sealed by the cover plate to formed a sealed cavity. A phase changing material is filled in the sealed cavity.

A lighting device includes a light emitting element having element electrodes; a light guide member to receive incoming light from the light emitting element and to emit light spreading along a plane; and a substrate including a base substitute. Conductors are formed on a first surface of the base substrate. An adhesive member is formed on a second surface of the base substrate, and through-holes penetrating the substrate in a thickness direction of the substrate. The substrate is provided on the light emitting element via the adhesive member of the substrate such that a surface of the light emitting element is exposed through each of the through-holes to define a bottomed hole. Each of the element electrodes is connected to each of the conductors via a filler filling the bottomed hole. The filler has a lower surface than a surface carrying the conductors of the substrate in a cross-sectional view.

The disclosed system generally comprises a damping module, a pressing module, a placement platform for placement of the multiple stacked planar objects and a compensatory mechanism engaging to the damping module. Particularly, the damping module includes a damper, a resilient component and an elongate support which are all arranged within a holder. Each of the stacked planar objects has a top planar surface and an underside planar surface as well as carries a plurality of corresponding holes, which become aligned accordingly to form a plurality of longitudinal grooves upon placement onto the platform. The head portion of the damper is substantially aligning with the positioned groove and abutting onto the underside surface of the bottommost stacked object. The compensatory mechanism is capable of adaptively adjusting position of the head portion of the damper in relation to the pressing ram at the vertical and/or horizontal plane.

Devices and methods related to metallization of ceramic substrates for shielding applications. In some embodiments, a method for fabricating a ceramic device can include forming a plurality of conductive features on or through a selected layer along a boundary between a first region and a second region, each conductive feature extending into the first region and the second region. The method can also include forming an assembly that includes the selected layer and one or more other layers. The method can further include separating the first region and the second region along the boundary such that each of the first region and the second region forms a side wall, the side wall including exposed portions of the conductive features, the exposed portions capable of forming electrical connection with a conductive shielding layer.

An embodiment of the invention may include a method, and resulting structure, of forming a semiconductor structure. The method may include forming a component hole from a first surface to a second surface of a base layer. The method may include placing an electrical component in the component hole. The electrical component has a conductive structure on both ends of the electrical component. The electrical component is substantially parallel to the first surface. The method may include forming a laminate layer on the first surface of the base layer, the second surface of the base layer, and between the base layer and the electrical component. The method may include creating a pair of via holes, where the pair of holes align with the conductive structures on both ends of the electrical component. The method may include forming a conductive via in the pair of via holes.

A circuit board includes a board body and pair of connection portions disposed at both ends of the board body. Each of the pair of connection portions is inserted into a connector. Each of the pair of connection portions includes a connection terminal electrically connected to the connector, and at least one of the pair of connection portions includes an extending portion extending from the connection terminal to an insertion leading end of the at least one of the pair of connection portion. The extending portion is disposed at a position to avoid a virtual line extending in an insertion direction through a position where the connector and the connection terminal are electrically connected.

A method of making a printed circuit board structure including a closed cavity is provided. The method can include the steps of forming a cavity in a core structure of a core layer, laminating each of a top surface and a bottom surface of the core structure with an adhesive layer and a metal layer to prepare a laminate structure and cover the cavity to define a closed cavity. The method also includes forming vias through the laminate structure, and patterning the metal layers in the laminate structure.

A method of making a printed circuit board structure including a closed cavity is provided. The method can include the steps of forming a cavity in a core structure of a core layer, laminating each of a top surface and a bottom surface of the core structure with an adhesive layer and a metal layer to prepare a laminate structure and cover the cavity to define a closed cavity. The method also includes forming vias through the laminate structure, and patterning the metal layers in the laminate structure.

A circuit board includes a substrate having a through hole, a circuit layer, a first measurement mark and a second measurement mark. According to the first and second measurement marks, an electronic detection device can measure a first distance between a first edge of the through hole and the first measurement mark and a second distance between a second edge of the through hole and the second measurement mark to determine whether the through hole has an undesired size or shift.

An assembly comprises a flexible circuit board (FCB) having a substrate with a top side, and a circuit pattern layer on the top side of the substrate. The circuit pattern layer has a connection region for facilitating electrical interconnection to the FCB, and one or more cavities extending through both the substrate and the circuit pattern layer. A first conductive layer for electro-magnetic interference (EMI) shielding is positioned on a top side of the FCB, and a second conductive layer for EMI shielding is positioned on a back side of the FCB. Electrically conductive adhesive extends through the one or more cavities for electrically connecting the first conductive layer and the second conductive layer. The electrically conductive adhesive further extends from the first conductive layer to the connection region for facilitating electrical interconnection of the first conductive layer and the second conductive layer.