A circuit board includes a substrate including first and second sections with different thicknesses, a protective layer, and mounting electrodes. The substrate includes a step surface connecting a first principal surface of the first section and a first principal surface of the second section. The mounting electrodes are on the first principal surface corresponding to an element to be mounted. The protective layer is disposed over the first principal surface, the step surface, and the first principal surface. The separation distance between the mounting electrode and the step surface is greater than or equal to the terminal-to-terminal distance between the mounting electrode and the mounting electrode.

A printed circuit board includes a rigid part including a central insulating layer for insulation, inner copper foil layers including a first conductive circuit portion, outer insulating layers for insulation, and outer copper foil layers including a second conductive circuit portion, wherein ones of the inner copper foil layers, the outer insulating layers, and the outer copper foil layers are symmetrically positioned on opposite sides of the central insulating layer and are sequentially laminated, and a flexible part formed by selectively removing a portion of the rigid part up to one side of the central insulating layer.

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.

Apparatus for transferring conductive patterns to a substrate (56), comprising a module (52) configured to transfer a pattern (63) of sinterable material (63a) to said substrate (56) and an optical module (12) to perform a sintering of the transferred pattern (63a). Said apparatus comprises one or more self-propelled pattern transferring units (52) comprising a module configured to move said self-propelled unit (14, 20) over said substrate (56) under the control of movement instructions (53b) associated to a motor (16, 21), said self-propelled unit (14, 20) comprising said module (52) configured to transfer a pattern (63a) of sinterable material (CI) to said substrate (56) obtaining a transferred pattern (63a) and comprising also said optical module (12) to perform a sintering of the transferred pattern (63a) on said substrate (56) obtaining a sintered pattern (63b, 63c).

In a circuit forming device, a resin laminated body is formed by curing an ultraviolet curable resin ejected by an ejecting device. Then, ultraviolet curable resin is ejected into a cavity of the resin laminated body, and an electronic component is placed on the ultraviolet curable resin. Then, the electronic component is cured and the electronic component is fixed.

A copper clad laminate includes: an insulating layer containing a cured product of a resin composition; and a surface treated copper foil on one surface or both surfaces of the insulating layer, the resin composition containing a polymer, and the surface treated copper foil including a finely roughened particle treatment layer of copper on at least one surface side of a copper foil, the finely roughened particle treatment layer being formed of fine copper particles having a particle size of 40 to 200 nm, a heat resistance treatment layer containing nickel provided on the finely roughened particle treatment layer, a rust prevention treatment layer containing at least chromium provided on the heat resistance treatment layer, a silane coupling agent layer provided on the rust prevention treatment layer, and an amount of nickel attached in the heat resistance treatment layer being 30 to 60 mg/m.sup.2.

A method for manufacturing a flexible circuit board includes providing a first laminated structure, the first laminated structure including two first wiring boards, a first adhesive layer sandwiched between the two first wiring boards, and a first conductive structure. The first conductive structure penetrates the two first wiring boards and the first adhesive layer and electrically connects the two first wiring boards. The first adhesive layer defines a first opening, the first opening includes a first edge away from the first conductive structure. The first laminated structure is cut along the first edge and then the two first wiring boards are unfolded. A flexible circuit board manufactured by such method is also disclosed.

A display device includes a display module and a circuit board. The display module includes a base substrate, which includes a display area and a non-display area adjacent to the display area, and a first pad positioned on the base substrate and overlapping the non-display area. The circuit board includes a first board and a second pad positioned on the first board and contacting the first pad, wherein the second pad is provided with a first metal layer of a single material.

A flexible printed circuit board (PCB) may have one or more coin cell batteries mounted thereto such that the flexibility of the flexible PCB is maintained. The flexible PCB has one or more battery contact pads fabricated thereon. Each battery contact pad includes a pattern of metalized vias each extending from a top surface to a bottom surface of the flexible PCB. A coin cell battery may be positioned over or under the battery contact pad. Conductive light curable epoxy is applied to and in each metalized via to contact and adhere to the coin cell battery to form a conductive path from the battery through the battery contact pad to printed conductors on the flexible PCB. Methods of mounting one or more coin cell batteries to a flexible PCB are also provided, as are other aspects.

A display device includes a display module and a circuit board. The display module includes a base substrate, which includes a display area and a non-display area adjacent to the display area, and a first pad positioned on the base substrate and overlapping the non-display area. The circuit board includes a first board and a second pad positioned on the first board and contacting the first pad, wherein the second pad is provided with a first metal layer of a single material.