An information handling system includes a first z-axis compression connector, a first dual in-line memory module (DIMM), a second z-axis compression connector, a second DIMM, and a printed circuit board. A first side of the first compression connector is affixed to the printed circuit board. A first surface of a first memory circuit board of the first DIMM is affixed to a second side of the compression connector. A first side of the second compression connector is affixed to a second side of the first memory circuit board. A first side of a second memory circuit board of the second DIMM is affixed to a second side of the second compression connector. The first compression connector has a first depth, and the second compression connector has a second depth that is different from the first depth.

A cable connection apparatus, a connection assembly, and a method for manufacturing the connection assembly are provided. The cable connection apparatus includes: a back plate and a connection member. The back plate includes a plate body and a ground layer. The plate body defines a through hole and a plurality of shielding holes. The plurality of shielding holes are defined at a periphery of the through hole. The ground layer is arranged on each of two opposite sides of the plate body and is connected to each of the plurality of shielding holes. The connection member abuts against or connects to a surface of a side of the back plate arranged with the ground layer. The connection member is arranged with a signal pin, and the signal pin is received in the through hole.

Various embodiments of the present disclosure are directed to electrically conductive connection between a first electrically conductive element and a second electrically conductive element on a textile carrier material. In one example embodiment, the electrically conductive connection includes an electrically conductive thermal transfer adhesive arranged on the carrier material and creates an electrically conductive connection between the first conductive element and the second conductive element. The electrically conductive connection is positioned in electrically conductive contact with the first conductive element and the second conductive element.

A wiring substrate is connected to a backplane, and includes: a first connector that is mounted on one surface of the wiring substrate and is connected to the backplane; an opening portion that is formed in the one surface on a side opposite to a side connected to the backplane of the first connector, and through which a cable having one end connected to the first connector is passed; an integrated circuit that is mounted on the one surface on a side opposite to a side on which the first connector is present relative to the opening portion; and a second connector that is mounted on the other surface on a side opposite to the one surface in the vicinity of the integrated circuit on the side opposite to the side on which the first connector is present relative to the opening portion, is connected to the integrated circuit via a through hole penetrating the wiring substrate, and is connected to the other end of the cable.

An electrical cable (1000) including a plurality of substantially parallel insulated conductors (100) is described. Each insulated conductor (100) includes an electrically conductive inner conductor (200) co-extensive and covered with an insulating layer (300). At least a portion of a periphery of each insulated conductor (100) may be encompassed by a substantially co-extensive electrically conductive shield (400). For each insulated conductor (100), portions of the insulating layer (300) are removed from the top side (1200) of the cable (1000) to expose a portion of the inner conductor (200) of the insulated conductor (100). The insulated conductor (100) is adapted to mate with an electrically conductive mating conductor (500) at the exposed portion (210) of the inner conductor (200).

An adaptor includes a substrate, a first housing, and a flat cable. The substrate comprises a terminal hole. The first housing includes a first insertion hole and a second insertion hole. The substrate is inserted into the first insertion hole. The flat cable includes a plurality of conductors. Each of the conductors includes a conductor terminal. The flat cable passes through the second insertion hole. The conductor terminal is connected to the terminal hole. A direction in which the substrate is inserted into the first insertion hole is perpendicular to a direction in which the flat cable passes through the second insertion hole.

The present invention discloses an electrical connector and an electrical connector assembly. The electrical connector includes a circuit board, a connection port, and an insulating member. The circuit board has a conductive region, located on a surface of the circuit board. The connection port is arranged on the surface of the circuit board, and the connection port is electrically connected to the circuit board. The insulating member is arranged on the circuit board, and surrounds an outer periphery of the connection port. The insulating member includes a metal layer, arranged on an outer surface of the insulating member.

A flexible cable jumper structure and manufacturing method thereof. The flexible cable jumper device of the present disclosure includes a cover layer, a first metal layer stacked on the cover layer and having a circuit pattern formed thereon, a first dielectric layer stacked on the first metal layer, a first adhesive layer applied on the first dielectric layer, a second metal layer stacked on the first dielectric layer to which the first adhesive layer is applied and having a circuit pattern formed thereon, a heat-resistant layer stacked on the second metal layer, and a terminal layer formed in one region of the heat-resistant layer and electrically connected to the first metal layer and the second metal layer.

This application relates to a chip-to-module cable assembly, includes a first joint, a second joint and a first flexible PCB cable, the flexible PCB cable, including flexible material parts located on upper and lower layers and a connection portion located on a middle layer, wherein the connection portion comprises two rigid material portions respectively located at end portions of the flexible material parts on the upper and lower layers and a hollow portion between the two rigid material portions, the flexible material parts each comprises at least one conducting wire, one end of each of the at least one conducting wire is connected to a first interface terminal of the first joint, and another end of the conducting wire is connected to a second interface terminal of a second joint.

A connector includes a pushing member including a projection and a pushing member-side flange formed at a root portion of the projection, and a contact having a projection accommodating portion, the pushing member-side flange including a pair of fixing portions separately arranged on opposite sides of the root portion of the projection across the projection, when the projection is inserted into the projection accommodating portion together with the flexible conductor with a part of the flexible conductor being laid along a lateral surface of the projection being fixed by the pair of fixing portions, the part of the flexible conductor laid along the lateral surface of the projection being sandwiched between the lateral surface of the projection and an inner surface of the projection accommodating portion to contact the inner surface of the projection accommodating portion, whereby the contact is electrically connected to the flexible conductor.