A circuit board assembly for electronic devices includes a circuit board having a first surface and a second surface opposite the first surface, and a heat sink carrier disposed on the first surface of the circuit board. The heat sink carrier includes at least one clamp portion. The assembly also includes a heat sink. The heat sink is positioned in the at least one clamp portion of the heat sink carrier to transfer heat from one or more electronic devices to the heat sink via the heat sink carrier.

According to one embodiment, an electronic device includes a housing with a through-hole, a flexible printed circuit inserted through the through hole and including a first connection portion on an inner side of the housing with first connection pads and a second connection portion on an outer side of the housing with second connection pads, a first electrical component in the housing, and a first connector connected to the first electrical component and including connection terminals contacting the first connection pads. A first pad of the first connection pads is greater than other first connection pads.

A module assembly is attached on a headlining of a vehicle and includes a base where an upper portion thereof is open, a first printed circuit board (PCB) and a second PCB sequentially stacked on a plurality of supporting pillars extending in a vertical direction to an inner bottom surface of the base and electrically connected to each other by a flexible cable, and a cover assembled with the base to cover the first and second PCBs stacked on the base.

Semiconductor devices having an array of flexible connectors configured to mitigate thermomechanical stresses, and associated systems and methods, are disclosed herein. In one embodiment, a semiconductor assembly includes a substrate coupled to an array of flexible connectors. Each flexible connector can be transformed between a resting configuration and a loaded configuration. Each flexible connector can include a conductive wire electrically coupled to the substrate and a support material at least partially surrounding the conductive wire. The conductive wire can have a first shape when the flexible connector is in the resting configuration and a second, different shape when the flexible connector is in the loaded configuration.

A circuit board assembly for electronic devices includes a circuit board having a first surface and a second surface opposite the first surface, and a heat sink carrier disposed on the first surface of the circuit board. The heat sink carrier includes at least one clamp portion. The assembly also includes a heat sink. The heat sink is positioned in the at least one clamp portion of the heat sink carrier to transfer heat from one or more electronic devices to the heat sink via the heat sink carrier.

Disclosed is an electronic device. An electronic device according to an embodiment may include: a housing including a first plate oriented in a first direction, a second plate oriented in a second direction opposite the first direction, and a side face surrounding a space between the first plate and the second plate; a first PCB disposed in the space and including a first face oriented in the first direction, a second face oriented in the second direction, and a first electrical connector disposed on the first face; a second PCB disposed in the space closer to the second plate than the first PCB, and including a second electrical connector; a third electrical connector detachably coupled to the first electrical connector; a fourth electrical connector detachably coupled to the second electrical connector; an FPCB electrically connected between the third connector and the fourth electrical connector, and including a first portion facing the second face; and a flexible conductive member comprising a conductor disposed between the second face and the first portion.

A functional contactor is provided. The functional contactor contains a conductive elastic portion having elasticity and electrically contacting one of a circuit board of an electronic device, a bracket coupled to the circuit board, and a conductor which can come into contact with the human body; a substrate containing a plurality of dielectric layers; and a functional element embedded in the substrate so as to be electrically connected in series to the conductive elastic portion.

An installation structure of a temperature fuse is disclosed. The temperature fuse includes a first leg fixed to one surface of a printed circuit board (PCB), a bent part formed to be bent several times in an outer direction of the PCB from an end part of the first leg, and a second leg incorporated with the bent part and fixed to one surface of the PCB while being spaced apart from the first leg by a predetermined distance. The installation structure of the temperature fuse includes a third leg formed to extend from any one of the first leg and the second leg, a conductive member electrically connected to the third leg while being electrically isolated from the PCB, and a sensing part electrically connected to the third leg through the conductive member, and configured to detect whether a connection state between the third leg and the conductive member is normal.

Each of a supporting-terminal-equipped capacitor chip and a mounted structure thereof includes a capacitor chip and first and second supporting terminals that each have electric conductivity. A maximum diameter size of the first supporting terminal when viewed in an axial direction is larger than a maximum length size of a portion of a first outer electrode on a second main surface in a length direction. A maximum diameter size of the second supporting terminal when viewed in the axial direction is larger than a maximum length size of a portion of a second outer electrode on the second main surface in the length direction.

There are provided an electrical connection structure, an electrical connection method and an electric connector capable of improving contact reliability, and an electric device including the electrical connection structure. The electrical connection structure includes a swage part configured to sandwich a first electric conductor and a sheet member having a second electric conductor, and an elastic member provided between the first electric conductor and the sheet member in a sandwiching portion of the swage part, the elastic member being configured to connect between the first electric conductor and the sheet member. The first electric conductor and the second electric conductor are electrically connected to each other via a contact point provided in the first electric conductor and a contact point provided in the second electric conductor in the sandwiching portion.