Provided is an electronic equipment which can effectively reduce unexpected unnecessary radiation. In the electronic equipment, a circuit board on which a noise source that is an electronic part becoming a source of the unnecessary radiation is mounted and a circuit board mounting plate on which the circuit board is mounted are disposed substantially parallel with a space put therebetween. In the electronic equipment, a partition plate is disposed, which functions as a noise reflecting surface on which an indirect wave emitted from the noise source towards the circuit board mounting plate is reflected. Further, an indirect wave dispersing member is disposed between the circuit board and the circuit board mounting plate so as to block spacing between the noise source and the partition plate.

The disclosure provides a server including a housing, a plurality of hash boards, a power module and an electrical connection board. Each hash board is slidably arranged in a first accommodating space. The plurality of hash boards and the power module are respectively connected to the electrical connection board. The power module supplies power to the plurality of hash boards through the electrical connection board. The electrical connection board includes two conductive connection boards, each of which is provided with a plurality of conductive pins. The pins form multiple pairs of conductive pins in one-to-one correspondence. Each pair of conductive pins corresponds to each hash board and is electrically connected to supply power to the hash board. Each pair of conductive pins is detachably matched with each hash board to connect or disconnect the power supply path of the hash board.

An electrical interconnection system comprises a bifurcated, multilayer flex circuit having electrode pads on the inner surfaces of the bifurcation. Electronic components are mounted on one or both sides of the flex circuit by conventional means. When the bifurcation is spread apart, the electrode pads are alignable with respective contacts on a printed circuit board. After bonding the pads to the contacts by soldering, conductive adhesive, or other means, a secure electrical connection is maintained while still allowing the flex circuit to bend somewhat from side to side, creating additional design options not available with rigidly mounted components and modules.

An electronic device is disclosed, including: a first support member including at least one screw-fastening portion; a first printed circuit board (PCB) stacked on the first support member and including at least one screw-fixing portion facing the at least one screw-fastening portion; a second PCB spaced apart from the first PCB, including a first screw guide groove; an interposer disposed between the first PCB and the second PCB electrically connecting them and including a second screw guide groove facing the first screw guide groove; and a second support member stacked on the second PCB and including a screw inlet portion facing the first screw guide groove. The second support member, the first PCB, and the first support member are fixed to each other via a screw inserted through the screw inlet portion.

An electrical connection of an electronic component, such as an inductor, and a circuit board is implemented as follows. The circuit board has a through-hole and is located at a distance from an inner bottom surface of the case. An electronic component is around the through-hole and between the inner bottom surface and the circuit board. The electronic component has a conducting wire and a conducting plate. The conductive connector is between the through-hole and the conducting plate and electrically connected to the conducting plate. The electronic component is electrically connected to the circuit board through the conductive connector. The insulated connector corresponds to the conductive connector and is between the conducting plate and the inner bottom surface. The fastener is connected to the conductive connector through the through-hole. Thus, a good electrical connection between the electronic component and the circuit board is achieved.

A connection structure between a printed circuit board and a terminal block includes: an insertion portion at one end of the printed circuit board with a pattern disposed thereon; a terminal-block main body including a receiving port that receives the insertion portion; a nut held in the terminal-block main body; and a screw tightened into the nut. The pattern is interposed between the screw and the nut when the insertion portion is inserted into the receiving port.

The invention discloses a terminal and an electronic device having the same. The terminal includes a connecting part, a mounting part, and a fixing part along an insertion direction, wherein the connecting part is adapted to be connected to a jump wire of an electronic component, the mounting part has an outer profile matching with at least a portion of an inner profile of an insertion hole in a base, for restricting displacement of the terminal after being inserted into the insertion hole, and the fixing part is adapted to be threadedly connected with the a fixing member so as to connect the fixing part to a circuit board.

The disclosure relates to a communication technique and system after 4G systems for combining a 5G communication system with IoT technology to support higher data rates. Based on 5G communication and IoT-related technologies, the disclosure can be applied to intelligent services (e.g., smart home, smart building, smart city, smart or connected car, healthcare, digital education, retail, security, and safety). A converter may include: a first printed circuit board having a first controller for power conversion disposed on an inner surface of the first printed circuit board, the inner surface of the first printed circuit board comprised in an inner surface of the converter; a second printed circuit board having a second controller for power conversion disposed on an inner surface of the second printed circuit board, the inner surface of the second printed circuit board facing the inner surface of the first printed circuit board and comprised in the inner surface of the converter; first connectors disposed on the inner surface of the first printed circuit board; and second connectors disposed on the inner surface of the second printed circuit board, the second connectors configured to be coupled with the first connectors.

Provided are a communication system and a communication apparatus thereof, the communication apparatus includes: a bottom case and a printed circuit board mounted on the bottom case, the communication apparatus further includes a heat-conductive mounting strip, the printed circuit board being mounted on the bottom case by means of the heat-conductive mounting strip, wherein a lower end surface of the heat-conductive mounting strip is connected to the bottom case, and an upper end surface of the heat-conductive mounting strip is connected to the printed circuit board.

An electronic apparatus includes a conductive member and a printed circuit board, wherein the printed circuit board includes a printed wiring board having a signal wiring formed thereon, a first semiconductor device configured to output a digital signal to the signal wiring, and a second semiconductor device configured to input the digital signal output from the first semiconductor device via the signal wiring, wherein the signal wiring has a signal wiring pattern formed on a surficial layer located opposite the conductive member in the printed wiring board, and wherein the conductive member has an aperture formed therein and located opposite the signal wiring pattern or includes a flat plate portion and a recessed portion recessed in a direction more away from the printed wiring board than the flat plate portion.