A circuit board heat sink structure having a circuit board and comprising a metallic heat sink, wherein the circuit board has a metal substrate, an insulation layer and a conductor layer, and the wherein the circuit board is arranged on the heat sink in such a way that the metal substrate contacts a locating face of the heat sink. At least one heat transition point is formed between the heat sink and the metal substrate, which provides a defined metallic contact between the material of the heat sink and the material of the metal substrate. A method is also provided for forming the circuit board heat sink structure.

An electrical contact pin is intended for pressing into a hole which is provided in a circuit carrier board and has a circumferential wall with a metallized surface. The contact pin consists mainly of copper or of a copper alloy and is surrounded by a layer which includes tin at least in a part region which is to be pressed into the hole. The layer, which includes tin, forms the surface of the contact pin and includes substantially only tin and tin oxide, wherein the tin oxide is formed by way of electrolytic oxidation and the concentration thereof is greatest on the surface of the layer.

A printed wiring board includes a main substrate and a rising substrate. A support portion of the rising substrate is inserted into a slit in the main substrate. In a direction in which a plurality of first electrodes are aligned, a width of each of the plurality of first electrodes is larger than a width of each of a plurality of second electrodes, and the width of each of the plurality of second electrodes is arranged to fit within the width of each of the plurality of first electrodes.

A display device including a film substrate including first and second surfaces, the first surface being opposite to the second surface; a semiconductor chip disposed on the first surface and including an input terminal and a test terminal, which are arranged in a first direction; a first wire extending from the input terminal on the first surface along a second direction, which intersects the first direction; and a second wire including a first extended portion, which extends along the first surface, a second extended portion, which extends along the second surface, and a first via, which penetrates the film substrate and connects the first extended portion and the second extended portion, wherein the first extended portion extends from the test terminal in the second direction and is connected to the first via, and the second extended portion extends from the first via to an edge of the second surface.

A power control module includes a power device having a first side and a second side opposite from the first. The power control module includes a printed wiring board (PWB) spaced apart from the first side of the power device. The PWB is electrically connected to the power device. A heat sink plate is soldered to a second side of the transistor for heat dissipation from the transistor. The PWB and/or the heat sink plate includes an access hole defined therein to allow for access to the transistor during assembly. A method of assembling a power control module includes soldering at least one lead of a power device to a printed wiring board (PWB), pushing the power device toward a heat sink plate, and soldering the power device to the heat sink plate.

A printed wiring board includes a main substrate and a rising substrate. A support portion of the rising substrate is inserted into a slit in the main substrate. In a direction in which a plurality of first electrodes are aligned, a width of each of the plurality of first electrodes is larger than a width of each of a plurality of second electrodes, and the width of each of the plurality of second electrodes is arranged to fit within the width of each of the plurality of first electrodes.

A display device including a film substrate including first and second surfaces, the first surface being opposite to the second surface; a semiconductor chip disposed on the first surface and including an input terminal and a test terminal, which are arranged in a first direction; a first wire extending from the input terminal on the first surface along a second direction, which intersects the first direction; and a second wire including a first extended portion, which extends along the first surface, a second extended portion, which extends along the second surface, and a first via, which penetrates the film substrate and connects the first extended portion and the second extended portion, wherein the first extended portion extends from the test terminal in the second direction and is connected to the first via, and the second extended portion extends from the first via to an edge of the second surface.

A display device and a method of manufacturing the display device are capable of substantially minimizing damage to a display panel. The display device includes: a first substrate including a display area and a pad area; a polarization film disposed at an upper surface of the first substrate to overlap the display area; a flexible printed circuit board disposed at a lower surface of the first substrate; a via hole defined through the first substrate at the pad area; and a connection metal located at the via hole. The connection metal includes a connection portion disposed in the via hole and a first protruding portion that protrudes with respect to the first substrate, and the polarization film is spaced apart from the via hole in a plan view.

Attaching electronic components to a substrate can be challenging in certain applications. By utilizing printed conductive ink to fill vias, one or more conductive layers may be provided, which allow for fine pin pitches or other crowded substrates to utilize multiple layers for traces connecting the contact pad to the pins of an electronic component. By applying a substrate with conductive ink and then selectively applying a solderable ink on the conductive ink, and with conductive ink filling the vias, electronic components may be attached to a substrate that provides mechanical attachment and electrical connectivity which may also be formable or flexible.

Various back-drilled via probing techniques are described. In some cases, a screw may be utilized to establish a conductive pathway through a voided portion of a back-drilled via to a plated portion of the back-drilled via to enable back-drilled via probing. In other cases, a combination of solder paste and a wire may be utilized to establish the conductive pathway to enable back-drilled via probing. In other cases, a compliant pin that includes a metallized particle interconnect material may be utilized to establish the conductive pathway to enable back-drilled via probing. In other cases, a combination of an ultraviolet curable film and a light pipe may be utilized to establish a conductive pathway the conductive pathway to enable back-drilled via probing.