A power supply device of an electronic apparatus includes: a power input portion configured to receive alternating current (AC) power; a rectifier-smoother configured to rectify and smooth the received AC power and output the AC power; a power converter configured to convert a level of a voltage output from the rectifier-smoother to supply operating power to the electronic apparatus; a board on which the power input portion, the rectifier-smoother, and the power converter are provided; and a waterproof coating layer formed in an area on the board corresponding to a position of the power converter to prevent infiltration of moisture from an outside.

An organic substrate includes a core layer including organic materials; a first buildup layer on a top surface of the core layer; a second buildup layer on a bottom surface of the core layer; and at least one correction layer formed on at least one part of surfaces of the first buildup layer and the second buildup layer, wherein the correction layer has a thickness which has been calculated using properties of constituent materials including the coefficient of thermal expansion (CTE) and the Young's modulus of the core layer, and CTEs and the Young's modulus of the first and the second buildup layers for reducing warpage of the organic substrate.

An electromagnetic interference (EMI) shielding structure and a manufacturing method thereof are provided. The EMI shielding structure includes a printed circuit board (PCB), a plurality of elements mounted on a region of the PCB, an insulating dam provided on a peripheral portion of the region of the PCB and covering a portion of the plurality of elements; an insulating member provided on a remaining portion of the region the PCB that is surrounded by the insulating dam and covering a remaining portion of the plurality of elements; and a shielding layer covering outer surfaces of the insulating dam and the insulating member.

The proposed masking dam protects ball grid array integrated circuit components from conformal coating overflow, preventing joint breakage and thermal mismatch. The masking dam includes a frame with an integrated seal, a cover, and a fastening mechanism. The frame is sealed to a circuit board surround a component, the cover is attached to the frame, and the masking dam is secured to protect the component.

A wiring board includes a substrate, an electrode on a surface of the substrate, a wall surface in a ring shape surrounding an outer circumference of the electrode, an upper end of the wall surface is located at a position higher than a surface of the electrode, and a protrusion at the upper end of the wall surface, the protrusion protruding with respect to the wall surface inward of a ring shape defined by the wall surface.

A wiring substrate includes a first insulation layer having a component mounting area and a mark formation area, an electrode pad arranged in the component mounting area and having an upper surface exposed from the first insulation layer and a side surface and a lower surface embedded in the first insulation layer, and a mark arranged in the mark formation area and formed of an insulation pattern layer having an upper surface exposed from the first insulation layer and a side surface and a lower surface embedded in the first insulation layer. A color of the first insulation layer and a color of the insulation pattern layer are different.

A display device includes a display area including a light emitting element and an organic insulating layer on the light emitting element; and a non-display area adjacent to the display area in a first direction, the non-display area including a first dam spaced apart from the organic insulating layer in the first direction, and a first groove between the organic insulating layer and the first dam in the first direction.

The present disclosure relates to a method for the process-reliable soldering of a chip package onto a printed circuit board for the process-reliable soldering of a chip package. The printed circuit board has a metallic cooling surface, a plurality of metallic contact surfaces surrounding the cooling surface, and, on a side opposite the cooling surface, a rear metallic mating surface, the mating surface being connected to the cooling surface by open vias, and lanes of solder resist being arranged on the cooling surface, which lanes both divide the cooling surface into a plurality of partial surfaces and enclose the vias.

A dielectric substrate has a first surface including a first terminal connector and a second terminal connector located along a first side surface. A recess is between the first terminal connector and the second terminal connector. The recess has a first inner surface continuous with the first terminal connector, a second inner surface continuous with the second terminal connector, and a bottom surface between the first inner surface and the second inner surface. The first terminal connector has first wettability with a bond on its surface, and a first region has second wettability with the bond on its surface lower than the first wettability.

The present disclosure relates to a printed circuit board and a method of manufacturing the same. The printed circuit board includes: an insulating layer; a plurality of pads disposed on the insulating layer; and a plurality of insulating walls that are disposed on the insulating layer and cover side surfaces of the plurality of pads, respectively, but are not disposed on upper surfaces of the plurality of pads. The plurality of insulating walls are disposed to be spaced apart from each other on the first insulating layer.