Various embodiments include a plug receptacle for an electrical plug-in connection for receiving a plug with electrical plug conductor comprising a contact region for electrical connection to the plug receptacle comprising: a housing with an insertion region into which the plug can be releasably inserted; an electrical plug receptacle conductor rigidly arranged in the housing; and an electrical connecting conductor floating in the housing configured to electrically connect the plug receptacle conductor to the plug conductor. The electrical connecting conductor exerts a connecting force onto the contact region of the plug conductor once inserted into the plug receptacle. The connecting force runs substantially orthogonally in relation to said contact region.

Embodiments of the invention provide an electrical terminal that provides wire termination at an edge of a printed circuit board. The electrical terminal includes a terminal body having a first corner, a cage clamp in the terminal body and defining a wire insert axis and a screw insert axis, and a base supporting the terminal body on the printed circuit board. The base is angled so that the first corner is aligned along a front plane defined along the edge of the printed circuit board.

A printed board has an elongated shape and is to be electrically coupled to a display panel via a flexible board. The printed board includes a first board section; and a second board section shorter in length than the first board section in a substantially perpendicular direction to a longitudinal direction of the printed board. The first board section and the second board section are disposed in a row in the longitudinal direction, each of the first board section and the second board section has a first end in the substantially perpendicular direction to the longitudinal direction, the first end of the first board section projects further than the first end of the second board section in the substantially perpendicular direction, and a connection portion to be connected to the flexible board is disposed at the first end of each of the first board section and the second board section.

A wiring board includes, a base plate that has a first surface, a second surface opposite to the first surface, and a side surface coupled to the first surface and the second surface, a conductor provided on the side surface, and a protrusion provided over the side surface. The protrusion partitions the conductor into a first portion on the side surface that extends to the first surface and a second portion on the side surface that extends to the second surface. The protrusion has a solder wettability lower than the conductor and protrudes from the conductor.

A light bulb is disclosed, and includes a screw shell defining a cavity, a screw shell insulator, and a driver board. The screw shell insulator defines a passageway that terminates in an aperture. The driver board includes a positive leg that projects from a proximal edge of the driver board, with a proximal end portion that protrudes outside of the aperture, and a negative leg that projects from the proximal edge of the driver board, with a proximal end portion that is electrically connected to the screw shell. The positive leg is configured to extend through the passageway to make electrical contact with a positive terminal of a light socket. Variants in which a base shell and the legs are configured for bayonet type, multifaceted reflector, and T8-like bases are also disclosed.

The present disclosure provides a display module and a method for coating the same, which can prevent and/or reduce the occurrence of black seam between display modules that are arranged adjacent to each other. According to an example aspect of the present disclosure, a display module includes a printed circuit board; a plurality of luminous elements arranged at predetermined intervals on the printed circuit board; and a coating layer comprising a coating disposed between the respective luminous elements, disposed around side surfaces of the respective luminous elements positioned at an outermost, and formed to have a height that is substantially equal to a height of the side surfaces of the luminous elements, the coating being configured to block side light of the respective luminous elements.

A riser card is disclosed. The riser card includes a circuit board that has two sides, two longitudinal edges extending along a length of the board, and two orthogonal edges extending along a width of the board. The card also includes a first bus connector along one of the longitudinal edges; a second bus connector on one side of the board extending substantially parallel to the longitudinal edges; and a third bus connector on the other side of the board extending substantially parallel to the orthogonal edges. The second bus connector is configured to connect an add-on unit to the card so that the add-on unit extends substantially perpendicular from the board. The third bus connector is configured to connect an add-on unit to the card so that the add-on unit extends substantially parallel to the board and the first edges.

Embodiments herein relate to a Printed Circuit Board, PCB, (1) and a terminal (2) for connecting the PCB (1) to an electrical component. The PCB (1) comprises a through-hole (11) for receiving the terminal (2). The through-hole (11) has a partially open side wall (12), wherein the side wall (12) is open along at least a part of a length (L) of the 5 through-hole (11) perpendicular to a radius (R) of the through-hole (11). This allows the terminal (2) to protrude through the open side wall (12) when received by the through-hole (11), such that a position of the terminal (2) is adjustable along the length of the open side wall (12). The terminal (2) comprises a base (21), adapted to be received by the through-hole (11) of the PCB (1) and to create a press fit with the side wall (12) of the through-hole 10 (11), and a pin (22) projecting from a surface (23) of the base (21). The pin (22) is adapted to protrude through the open side wall (12), when the base (21) is inserted into the through-hole (11) of the PCB (1). Furthermore, embodiments herein relate to a method for assembling a PCB module (120) comprising the terminal (2) and the PCB (1).

An electronic assembly 52 includes a plurality of circuit boards 70, 74, 78 each comprising engagement grooves 84 spaced around an outer wall. The assembly includes a plurality of spacers 72, 76 with alignment elements. The alignment elements comprise a first tab 92 and a first tab receiver 93 extending in a first axial direction. The alignment elements further comprising a second tab 90 extending in a second axial direction opposite the first and a second tab receiver 91 extending in the second axial direction. A first spacer 72 is disposed between a first circuit board 70 and a second circuit board 74. The first tab 92 of the first spacer 72 is disposed within a first engagement groove of the first circuit board 70. The second circuit board 74 is disposed between the first spacer 72 and a second spacer 76. A second tab 90 of the first spacer 72 is received in a second engagement groove 84 of the second circuit board 74 and a first tab receiver 93 of the second spacer 76.

A connector assembly includes a flexible cable that includes a casing, a plurality of electrical wires each having a first portion encapsulated by the casing and a second portion extending beyond the casing, and a fiber having a first portion encapsulated by the casing and a second portion extending beyond the casing. The connector assembly further includes a housing having a first end to receive the flexible cable and a second end with a connector to connect with another connector, and a circuit board disposed in the housing. The circuit board includes first terminals to connect with the plurality of electrical wires, second terminals to connect with the connector, a plurality of traces coupling respective first terminals with respective second terminals, and a cleat. The second portion of the fiber extends beyond the casing to the cleat and winds around the cleat.