A circuit board according to an embodiment of the present invention comprises: a first metal layer; an insulating layer disposed on the first metal layer and comprising boron nitride agglomerate particles coated with a resin; and a second metal layer disposed on the insulating layer, wherein: one of both surfaces of the first metal layer, on which the insulating layer is disposed, is in at least partial contact with one surface of the insulating layer; one of both surfaces of the second metal layer, on which the insulating layer is disposed, is in at least partial contact with the other surface of the insulating layer; a plurality of grooves are formed on a surface which is one of both surfaces of at least one of the first metal layer and the second metal layer and which has the insulating layer disposed thereon; at least some of the particles are arranged in at least some of the plurality of grooves; the width (W) of at least one of the plurality of grooves is 1 to 1.8 times D50 of the particles; and a ratio (D/W) of the depth (D) to the width (W) of at least one of the plurality of grooves is 0.2 to 0.3.

A printed circuit board includes: a first flexible base member; a first metal line disposed on the first flexible base member; a first plating line disposed on the first metal line and including a first connecting portion, a first interconnection portion extending from the first connecting portion, and a first bending portion extending from the first interconnection portion; a first protective layer covering the first interconnection portion and exposing the first connecting portion and the first bending portion; a connection part disposed on the first bending portion and connected to the first bending portion; a second protective layer extending from a side surface of the connection part; a second plating line disposed on the second protective layer; a second metal line disposed on the second plating line; and a second flexible base member disposed on the second metal line.

According to an embodiment, a structure is provided. The structure comprises a silicone formed product, water, and a protective member. The silicone formed product contains hydroxyl groups in at least a portion of a surface. The water is in contact with at least the portion of the surface containing the hydroxyl groups. The protective member retains the water.

A method of forming a protected connection between a first connecting element, optionally mounted on a support (202), and a second connecting element, the method comprising: (i) depositing a protective material (210) on the first connecting element and/or on the support; (ii) optionally depositing an overlying coating (212) on the protective material; and (iii) pushing the second connecting element and establishing a connection between the first connecting element and the second connecting element, the connection being protected by the protective material.

Optics over a light source, such as, but not limited to, an LED on a circuit board. The optic does not entirely encapsulate the LED but rather includes an inner surface such that an air gap exists between the optic and the LED. The optic may include a lens and may conform to the shape of the circuit board.

An extensible electroconductive wiring material includes a flexible electroconductive material and insulating elastic bodies and, wherein the flexible electroconductive material having an electroconductive layer has vent peripheral edge portions in which vent holes and/or vent slits are penetrated and aligned in series and/or in parallel along an energization direction of the electroconductive layer while the vent peripheral edge portions are energizably linked, and the vent peripheral edge portions is sealed and covered by the insulating elastic bodies, so as not to be exposed; and the insulating elastic bodies, have penetration slits, and/or penetration holes which penetrate therethrough while matching the vent peripheral edge portions and are smaller than the vent holes and the vent slits. The extensible electroconductive wiring module has a plurality of these extensible electroconductive wiring materials.

The present invention relates to a printed circuit board embedding a power die wherein interconnections between the power die and the printed circuit board are composed of micro/nano wires, the printed circuit board comprising a cavity wherein the power die is placed, and wherein the cavity is further filled with a dielectric fluid.

It is intended to provide a resin composition that suppresses the thermal expansion of a printed circuit board more than ever and also prevents the bleedout of substances from the printed circuit board, while maintaining a high glass transition temperature. The resin composition of the present invention contains an alkenyl-substituted nadimide, a maleimide compound, and an epoxy-modified cyclic silicone compound.

According to a first aspect, there is provided a computer structure comprising a first silicon substrate and a second silicon substrate. Computer circuitry configured to perform computing operations is formed in the first silicon substrate, which has a self-supporting depth and an inner facing surface. A plurality of distributed capacitance units are formed in the second silicon substrate, which has an inner facing surface located in overlap with the inner facing surface of the first substrate and is connected to the first substrate via a set of connectors arranged extending depthwise of the structure between the inner facing surfaces. The inner facing surfaces have matching planar surface dimensions. The second substrate has an outer facing surface on which are arranged a plurality of connector terminals for connecting the computer structure to a supply voltage. The second substrate has a smaller depth than the first substrate.

Provided is a fabricating method of a pattern, which includes preparing a first substrate having a first width and a first thickness, stretching the first substrate and preparing a second substrate having a second width and a second thickness, forming a base layer made of a material of a pattern which will be formed on the second substrate, removing a predetermined region of the base layer and forming a first pattern having a first line width and a first height on the second substrate, and removing a tensile force applied to the second substrate to restore the second substrate back to being the first substrate and forming a second pattern having a second line width and a second height on the first substrate. Fineness of a line width can be achieved by forming the first pattern in a state in which the substrate is stretched, contracting a line width of the first pattern while restoring the stretched substrate, and forming the second pattern having a contracted line width on the restored substrate such that high integration can be achieved.