A protection relay connection assembly (10) for connecting a current transformer (14) and/or a voltage transformer (16) of an electrical network (12) to a protection relay (18) is provided. The protection relay connection assembly (10) includes a protection relay data acquisition board (20) and a protection relay connector (22). The protection relay data acquisition board (20) includes a first current mating member (24) connectable to a current measurement sensor (28), the current measurement sensor (28) being connectable in use to the protection relay (18) and/or a first voltage mating member (26) connectable to a voltage measurement sensor (30), the voltage measurement sensor (30) being connectable in use to the protection relay (18). The protection relay connector (22) includes a second current mating member (36) connectable to the current transformer (14) and/or a second voltage mating member (38) connectable to the voltage transformer (16). The first current mating member (24) and the second current mating member (36) are selectively mateable with one another to permit a measured current waveform of the electrical network (12) to be transmitted from the current transformer (14) to the protection relay (18). The first voltage mating member (26) and the second voltage mating member (38) are shaped to be selectively mateable with one another to permit a measured voltage waveform of the electrical network (12) to be transmitted from the voltage transformer (16) to the protection relay (18). Wherein the first current mating member (24) is shaped to prevent mating of the first current mating member (24) with the second voltage mating member (38), and the first voltage mating member (26) is shaped to prevent mating of the first voltage mating member (26) with the second current mating member (36).

A circuit protection assembly has a protection element having a positive temperature coefficient of resistance and consisting of a polymer-based conductive composite material layer tightly clamped and fixed between two metal electrodes and a copper clad laminate having a through hole in a middle thereof, wherein the protection element is provided in the through hole, the copper clad laminate serves as a substrate for the circuit protection assembly and has an adhesive layer on an upper surface and a lower surface thereof, so as to cover the protection element in a space formed by the copper clad laminate and the upper and the lower adhesive layers. The protection element having a positive temperature coefficient of resistance is electrically connected to a protected circuit via a conductive part.

An embodiment provides a printed circuit board and an electronic component package including the same, the printed circuit board comprising: a data line layer; a ground layer disposed on the data line layer; a power line layer disposed on the ground layer; and insulation layers disposed between the data line layer and the ground layer and between the ground layer and the power line layer, respectively, wherein the ground layer comprises a common ground and a chassis ground electrically insulated from the common ground.

A device for fixing a camera module, comprising: a base part; and a fixing unit including a first fixing part for supporting one side of each of a plurality of boards, and a second fixing part for supporting the other side facing one side of each of the plurality of boards, wherein the plurality of first fixing parts extends in a first direction from the base part, and includes a plurality of protruding parts protruding in the direction perpendicular to the first direction in order to support one side of each of the plurality of boards, and the plurality of second fixing parts extends in the first direction from the base part, and includes a plurality of protruding parts for supporting the other side of each of the plurality of boards.

A vehicle includes an electric machine, a battery, an inverter, and a flexible circuit. The electric machine is configured to propel the vehicle. The inverter is configured to convert direct current from the battery into alternating current. The flexible circuit has a sensor embedded therein that is configured to measure a first phase of the alternating current. The sensor is secured to an output terminal of the inverter that is connected to a first winding phase of the electric machine.

An integrated circuit die has a peripheral edge and a seal ring extending along the peripheral edge and surrounding a functional integrated circuit area. A test logic circuit located within the functional integrated circuit area generates a serial input data signal for application to a first end of a sensing conductive wire line extending around the seal ring between the seal ring and the peripheral edge of the integrated circuit die. Propagation of the serial input data signal along the sensing conductive wire line produces a serial output data signal at a second end of the sensing conductive wire line. The test logic circuit compares data patterns of the serial input data signal and serial output data signal to detect damage at the peripheral edge of the integrated circuit die.

A chip package includes a high voltage withstanding substrate and a device chip. The high voltage withstanding substrate has a main body, a functional layer, and a grounding layer. The main body has a top surface, a bottom surface opposite the top surface, a through hole through the top surface and the bottom surface, and a sidewall surrounding the through hole. The functional layer is located on the top surface. The grounding layer covers the bottom surface and the sidewall. The device chip is located on the functional layer, and has a grounding pad that faces the main body. The grounding pad is electrically connected to the grounding layer in the through hole.

Provided is a high voltage bridge rectifier. The high voltage bridge rectifier includes a supporter, a substrate on the supporter, a plurality of equivalent diode circuits mounted on the substrate, interconnection lines, and terminals. The substrate may include an insulation layer, element pads disposed on a center of the insulation layer, and terminal pads disposed on an edge of the insulation layer to surround the element pads.

A converter, a first switch, a second switch, and an inverter are disposed in that order along a second direction, at a first position in a first direction. A reactor and a capacitor are disposed in that order along the second direction, at a second position in the first direction. Energy is stored in the reactor via the first switch. The capacitor is discharged via the second switch. At least one of a set of the reactor and the converter and a set of the capacitor and the inverter is disposed side by side along the first direction.

A grounding structure for power socket includes a grounding main body, which consists of a basic section, a first connecting section, a second connecting section, a grounding section and a contact section. The first and the second connecting section are separately downward extended from two opposite ends of the basic section, such that the basic section and the first and second connecting sections together define a receiving space in between them. The contact section is downward extended from a side edge of the basic section into the receiving space; and the first connecting section is outward bent at its lower end to form the grounding section. And, the grounding section is provided at an outer end with a grounding opening.