Encapsulated PCB assembly (1) for electrical connection to a high- or medium-voltage power conductor in a power distribution network of a national grid, comprising a) a PCB (10), delimited by a peripheral edge (20) and comprising a high-tension pad (60, 62) on a voltage of at least one kilovolt, b) an electrically insulating encapsulation body (70) in surface contact with, and enveloping, the high-tension pad and at least a portion of the PCB edge adjacent to the high-tension pad, c) a shielding layer (80) on an external surface (90) of the encapsulation body and for being held on electrical ground or on a low voltage to shield at least a low-voltage portion of the PCB. The high-tension pad extends to the peripheral edge of the PCB.

A flexible printed circuit board with improved ground efficiency is disclosed, and a flexible display module and an electronic device comprising the same is disclosed, wherein the flexible printed circuit board comprises a flexible circuit film having a circuit layer disposed on one surface of a base film, and a ground pad portion disposed on another surface of the base film; and a conductive cover member configured to cover the other surface of the base film and electrically connected with the ground pad portion, wherein the conductive cover member includes a cutting portion overlapped with the ground pad portion.

Disclosed herein are structures, devices, and methods for electrostatic discharge protection (ESDP) in integrated circuits (ICs). For example, in some embodiments, an IC package support may include: a first conductive structure in a dielectric material; a second conductive structure in the dielectric material; and a material in contact with the first conductive structure and the second conductive structure, wherein the material includes a polymer, and the material is different from the dielectric material. The material may act as a dielectric material below a trigger voltage, and as a conductive material above the trigger voltage.

Provided is a display apparatus including: a display panel including a display area and a peripheral area; a printed circuit board attached to the peripheral area and including a ground portion and a test electrode spaced apart from the ground portion; a connector including a plurality of connector terminals connected to an external control apparatus and electrically connecting the printed circuit board and the external control apparatus to each other; and a cover layer arranged on the printed circuit board and covering at least a part of the printed circuit board. Accordingly, not only the display quality and reliability of the electric characteristics of the display apparatus are improved, but also a loss is reduced and a yield is improved during manufacturing processes.

A printer for security paper, such as a multifunction printer, a printer, a facsimile machine or a copier, is configured to perform a printing operation by distinguishing between security paper and normal paper. The printer for security paper includes: a security paper sensor disposed on a printing paper feeding path; and a control unit for comparing a first sensing value sensed by the security paper sensor when printing paper to be determined is not present near the security paper sensor with one or more second sensing values sensed by the security paper sensor for the corresponding printing paper on the feeding path, during the course of conveying the corresponding printing paper on the feeding path, determining printing paper as security paper when a comparison value is above a predefined reference value, and determining printing paper as normal paper when the comparison value is below the predefined reference value.

The present disclosure provides a source driver and a display panel. The source driver includes a printed circuit board, a flip-chip film, a source driver chip, a first connection line, and a test point. The source driver chip is encapsulated on the flip-chip film and connected to the display panel through the first connection line, and the first connection line is connected to the test point, wherein a conductive pattern is formed on the flip-chip film, the conductive pattern is grounded through a ground line, and the conductive pattern includes a tip portion configured to form a tip discharge effect to discharge static electricity on the test point to the ground line. Therefore, the present disclosure can conduct static electricity through the tip portion when electrostatic discharge occurs, thereby preventing the electrostatic discharge from damaging the driver chip through a test point path.

An electricity meter (17) is described which includes a conductor (19) for transferring energy from a supply (20) to a load (21). The electricity meter (17) also includes a multi-layer printed circuit board (18) mechanically attached to the conductor (19). The multi-layer printed circuit board (18) includes two or more insulating layers (26, 27, 33, 34). The two or more insulating layers (26, 27, 33, 34) include a first insulating layer (26, 27) having an attachment surface (28) facing the conductor (19). The multi-layer printed circuit board (18) also includes a first conductive layer (29) including a first planar sensor coil (30). The first insulating layer (26, 27) is between the first conductive layer (29) and the conductor (19). The multi-layer printed circuit board (18) also includes a second conductive layer (31) including a second planar sensor coil (32). The multi-layer printed circuit board (18) also includes a second insulating layer (26, 33) between the first (29) and second (31) conductive layers. The first planar sensor coil (30) and the second planar sensor coil (32) are electrically connected to one another by a buried via (40), or the first planar sensor coil (30) and the second planar sensor coil (32) are electrically connected to one another by a blind via (38) extending inwards from a back surface (35) of the multi-layer printed circuit board (18), the back surface (35) being opposed to the attachment surface (28).

A display device includes a first substrate including a display area and a non-display area, which is on the periphery of the display area, a light-emitting element disposed on the first substrate and in the display area, a display signal line which is disposed on the first substrate and in the display area, extends in a first direction, and transmits a signal to the light-emitting element, a common voltage supply line disposed on the first substrate and in the non-display area, a pad disposed on the first substrate and in the non-display area, and electrically connected to the display signal line, and an indentation pad disposed on the first substrate and in the non-display area, and electrically connected to the common voltage supply line, where the indentation pad is disposed closer than the pad to edges of the first substrate in a second direction, which intersects the first direction.

The disclosure provides a circuit board that includes: a carrier element having a number of circuit board layers; a number of electronic components; a number of thermal interfaces; and a number of electrical interfaces. The electronic components are arranged directly on at least one of the surface sides on the carrier element. The opposite surface side of the carrier element is of potential-free design. Additionally, the circuit board with the electronic components is overlaid by a covering material in such a way that the electronic components are mechanically stabilized and the thermal and/or electrical interfaces are free of the covering material.

The present disclosure provides a touch screen and a manufacturing method thereof, a display substrate, and a touch display device. The touch screen includes: at least one metal mesh layer and electrostatic leading lines, wherein each metal mesh layer includes a plurality of electrodes insulated from each other, and the electrostatic leading lines extend among the plurality of electrodes of the at least one metal mesh layer and are connected to grounding wires, wherein the electrostatic leading lines are arranged to be insulated from the plurality of electrodes.