A lighting device including a light-emitter including light emitting elements, and a support having a first surface that carries a wiring line electrically connecting element electrodes of the light emitting elements and a light emitting surface, and a substrate including a base substrate, a conductor formed on a first surface of the base substrate, an adhesive member formed on a second surface of the base substrate, and a through-hole penetrating the substrate. A space is formed between the substrate and the light-emitter to communicate with a bottomed hole formed in a location of the through-hole as a result of adhering an adhesive surface of the adhesive member to a surface of the light-emitter having the wiring line formed thereon. The wiring line is connected to the conductor via a filler filling the bottomed hole, and the space is located outside an opening of the bottomed hole.

A method of producing an electrical through connection. A cut extending from a first surface to a second surface and separating the area into a first part and a second part is provided on an area of the flexible substrate. At least one of the first and second part is raised from a first plane of the first surface. A first wet conductive layer is printed on the first surface on and around the cut. The first wet layer is solidified into a first dried conductive layer. At least one of the first part and the second part is raised from a second plane of the second surface. A second wet conductive layer is printed on the second surface on and around the cut. The second wet conductive layer is solidified into a second dried conductive layer, which creates an electrical through connection with the first dried conductive layer.

A multilayer ceramic substrate includes: a plurality of ceramic layers 300a, 300b stacked together; a via hole 400a, 400b provided in each of the plurality of ceramic layers, the via holes of the plurality of ceramic layers being connected together in a layer stacking direction of the plurality of ceramic layers; a via wire 406a, 406b including an electrical conductor filled into each of the via holes; a first conductor 404a, 404b provided on an upper surface of at least one of the plurality of ceramic layers, the first conductor having an annular or partially annular shape surrounding the via wire; and a second conductor 403a, 403b including a first portion and a second portion, the first portion being located outside the first conductor on the upper surface of the at least one ceramic layer, the second portion overlying the first conductor, and an inner rim of the second portion being located outside an inner rim of the first conductor, wherein a thickness of the first conductor 404a, 404b is greater than a thickness of the second conductor 403a, 403b.

A printed circuit board includes a board portion and an electronic element. The board portion includes a first substrate having an element accommodating portion and second substrates laminated on outer surfaces of the first substrate. The electronic element is disposed in the element accommodating part. The electronic element includes a heat generating element and a heat radiating member coupled to an inactive surface of the heat generating element.

Methods, systems, devices, and products for constructing a downhole tool electronics module. Methods may include creating a circuit board by metallizing at least part of a first surface on a first side of a substrate to define at least one metallized area on the first surface, wherein the substrate comprises a ceramic material and includes: the first side, including at least (i) the first surface, and (ii) an elevated surface elevated from the first surface, and a second side opposite the first side; flattening at least partially the elevated surface to a predefined first flatness to create a mounting portion by removing material from the elevated surface; attaching an electronics component to the first surface; and mounting the circuit board on an electronics carrier by adhering at least part of the mounting portion to a mounting surface on the electronics carrier. Flattening at least partially the elevated surface to the predefined first flatness may be carried out by removing the material by areal grinding.

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 method of manufacturing a through hole of a substrate includes forming, to the substrate, a cutting hole surrounding a removal-target-part such that a connection part of the substrate remains, the connection part that connects the removal-target-part that is removed from the substrate and a remaining part other than the removal-target-part that has been removed, along a cutting line of the through hole formed to the substrate; applying plating on an area including an inner peripheral wall face of the cutting hole of the substrate; applying a film covering an opening of the cutting hole on a surface of the substrate applied with the plating and performing exposure and development of the film to form an etching resist covering an area including the opening of the cutting hole; performing etching of the plating applied on the substrate; removing the etching resist; and cutting the connection part to remove the removal-target-part.

Disclosed is a cavity forming method for a printed circuit board. The method includes: stacking a plurality of substrates to form a stacked structure, each substrate including a prepreg and a copper clad circuit formed on a surface of the prepreg; attaching a release film to an outer surface of the stacked structure; demarcating a cavity region by forming a cutting line in the release film and the underlying prepreg; and removing the released film and the underlying prepreg inside the demarcated cavity region, thereby forming a cavity. The method is advantageous in terms of easy processing, mass production, and low manufacturing cost for printed circuit boards. Further, a cavity having an exactly same size as an actually required size can be designed for a printed circuit board, and it is possible to prevent an adhesive component from seeping out into a cavity from prepregs during formation of the cavity.

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 multilayer ceramic substrate includes: a plurality of ceramic layers 300a, 300b stacked together; a via hole 400a, 400b provided in each of the plurality of ceramic layers, the via holes of the plurality of ceramic layers being connected together in a layer stacking direction of the plurality of ceramic layers; a via wire 406a, 406b including an electrical conductor filled into each of the via holes; a first conductor 404a, 404b provided on an upper surface of at least one of the plurality of ceramic layers, the first conductor having an annular or partially annular shape surrounding the via wire; and a second conductor 403a, 403b including a first portion and a second portion, the first portion being located outside the first conductor on the upper surface of the at least one ceramic layer, the second portion overlying the first conductor, and an inner rim of the second portion being located outside an inner rim of the first conductor, wherein a thickness of the first conductor 404a, 404b is greater than a thickness of the second conductor 403a, 403b.