A battery pack comprises a set of battery cells, a battery cell holder holding the battery cells, at least one battery strap having a first end connected to a terminal of one of the battery cells and a second end extending from the battery cell holder, a printed circuit board having a first side and a second side, components mounted on the second side of the printed circuit board, a trace on the second side of the printed circuit board extending from one components to a contact connected to the trace and mated with the second end of the at least one battery strap. Multiple vias extend from the first side to the second side, and the contact comprises a first portion having a through hole and a leg integrally formed with and approximately perpendicular to the first portion, the leg extending from the first side of the PCB to the second side of the PCB through a first via, the trace extending from the first via, the leg soldered to the second side of the PCB and the via and the through hole aligned with a second via adjacent to the first via, the through hole sized and configured to receive a PCB end of the strap, the PCB end of the strap soldered to the contact.

Provided are a battery apparatus including: a battery pack including a plurality of battery cells; a battery management system (BMS) for managing the plurality of battery cells; a board to which the BMS is mounted, the board including an insulation layer and a conductive layer; a plurality of wires extending from the plurality of battery cells onto the board; a plurality of through-holes formed in the board, the plurality of wires extending through the plurality of through-holes; a plurality of non-conductive areas, each of the plurality of non-conductive areas being formed on an area around a respective one of the plurality of through-holes; and a plurality of soldering parts, each of the plurality of soldering parts being formed on the respective one of the plurality of through-holes.

An optical module includes: a stem made of metal; a ground pin including a pin portion and a joint portion having a diameter larger than a diameter of the pin portion and joined to an outer flat surface of the stem; a flexible printed circuit including a wiring pattern on a front surface and a ground pattern having an exposed surface at a position facing the outer flat surface of the stem on a back surface, in which a tip portion of the pin portion of the ground pin penetrating a second through hole is electrically connected to the second through hole on the front surface; and a plate made of metal, having a back surface joined to the outer flat surface of the stem and a front surface joined to the exposed surface of the ground pattern.

An electronic device is downsized while suppressing performance degradation of the electronic device. In the electronic device, a power module including a power transistor is arranged in a first region on a back surface of a through hole board having a plurality of through hole vias having different sizes while a pre-driver including a control circuit is arranged in a second region on a front surface of the board. In this case, in a plan view, the first region and the second region have an overlapping region. The power module and the pre-driver are electrically connected to each other via a through hole via. The plurality of through hole vias include a through hole via having a first size, a through hole via which is larger than the first size and in which a cable can be inserted, and a through hole via in which a conductive member is embedded.

A component having electrical connector elements for making contact with a circuit board, optionally having additional securing elements for mechanical stability after soldering or positioning devices for supporting components with an unfavourable center of gravity or supporting elements which can optionally be removed after the soldering process. The positioning devices or supporting elements serve to position components with different forms on a circuit board and to keep them in the correct orientation for the soldering process. Fitting takes place in a force-free manner and thus favours automation and the use of for example pick-and-place robots which take hold of and move the particular component via the positioning device connected thereto, engaging with and/or around either a contact element or a supporting element. The support of the positioning device allows a stable state during the soldering process. In a corresponding manner, methods for carrying out the soldering processes are specified.

An electronic device includes at least two boards and support pillars. The at least two boards include hole portions. The support pillars inserted into the hole portions such that the at least two boards are held mutually separated. The hole portions include tapered surfaces that incline toward center portions of the hole portions from a surface on a side from which the support pillars of the boards are inserted.

A printed circuit assembly (PCA) that provides for a method of rebuilding an electrically operated automatic transmission solenoid module. The PCA allows for a repairable yet rugged interconnection of several solenoids that reside within the span of the module assembly.

A power semiconductor module includes an insulating circuit substrate; a printed circuit board disposed over the insulating circuit substrate; and a plurality of terminals each having a rod-shaped portion and including a first protrusion and a second protrusion each protruding laterally form a side face of the rod-shaped portion; wherein at least one of the plurality of terminals is inserted to one of the through-holes of the printed circuit board and is locked to the one of the through-holes via the first protrusion, and wherein at least another one of the plurality of terminals is inserted to another one of the through-holes of the printed circuit board and is locked to said another one of the through-holes via the second protrusion, and an end of the at least another one of the plurality of terminals is electrically connected to a conductive plate on the insulating circuit substrate.

A flexible substrate has an insulating base member and a conductive layer that is formed on the base member and includes an electrical connecting portion fixed to a component and electrically connected to the component, and the flexible substrate includes: a main portion on which the electrical connecting portion is formed; and a protruding portion provided so as to protrude from a portion of the main portion in which the electrical connecting portion is formed, wherein the main portion is bent along a first bending line extending in a first direction, and wherein the protruding portion can be bent along a second bending line extending in a second direction intersecting the first direction and is adapted to reduce stress occurring at the electrical connecting portion by the protruding portion being bent along the second bending line.

A flexible substrate includes: an insulating base member; a plurality of lands formed aligned in a plurality of lines in a first direction on the base member; and a plurality of wirings formed on the base member, extending in a second direction intersecting the first direction, and connected to the plurality of lands on each line of the plurality of lines, wherein the plurality of wirings include a wiring extending between the lands aligned in the first direction, and wherein each of the plurality of lands has a planar shape longer in the second direction.