A connector includes a contact retained in a housing selectively in one of a first posture and a second posture inverted 180 degrees around a fitting direction, the contact including a contact portion to be contacted with a contact of a counter connector and a connection portion to be connected to a flexible conductor of a connection object, between a case where the contact is retained in the housing in the first posture and a case where the contact is retained in the housing in the second posture, the contact portion is situated at a same position with respect to the housing and the connection portion is situated at a different position with respect to the housing, the contact being retained in the housing in, of the first posture and the second posture, a posture corresponding to an orientation of a flexible conductor exposed surface of the connection object.

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 method of manufacturing a wiring harness assembly includes the steps of forming a plurality of electrically conductive wires encased within a substrate formed of a dielectric material, forming an opening in the substrate located and sized such that a section of the plurality of electrically conductive wires is exposed within the opening, disposing a support segment within the opening, securing a connector segment including a plurality of terminals to the support segment, and placing the plurality of terminals in mechanical and electrical contact with the plurality of electrically conductive wires.

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

A wiring harness assembly includes a plurality of electrically conductive wires encased within a substrate formed of a dielectric material, a location feature integrally formed with the substrate, and an opening defined in the substrate located within a predetermined tolerance relative to the location feature. A section of the plurality of electrically conductive wires is exposed within the opening.

A connector assembly includes a connector and a flat cable. The connector includes a first terminal, a second terminal, a first body, a second body, a metal plate, a third body, and a shell. The first and second terminals electrically connect a first side and a second side of the flat cable respectively and are respectively contained in a first capacity slot and a first through-hole of the first body and in a second capacity slot and a second through-hole of the second body. The first and second bodies clamp the metal plate. The third body partly winds and fixes the first body and the second body, and protects a terminal conductive contact part of the flat cable connected by the first and second terminals to form the connector. The flat cable connects to the connector directly. There is no need for a fixed rigid printed circuit board.

[Problem] To provide an electrical connector with flat-type conductors, a counterpart electrical connector, and an electrical connector assembly, in which the size of the connector is not increased in the thickness direction of the flat-type conductors when using two flat-type conductors disposed in parallel opposite each other.

[Means of Solution] The flat-type conductors C1, C2, whose faces whereon the contact portions C1A-1, C2A-1 are arranged are used as interior side faces, have a pair of said interior side faces placed in a face-to-face relationship at locations spaced apart from each other in the thickness direction of the flat-type conductors C1, C2, and have a receiving space 10D, which is intended for receiving the nesting portion 54 of the counterpart electrical connector 2, formed between said pair of interior side faces; the housing 10 has a mating portion 10A which, along with holding and being able to support the front end sections of the flat-type conductors C1, C2, mates with a counterpart housing 50, and the mating portion 10A can support the exterior side faces with mating walls 11, 12 that are placed in a face-to-face relationship with the exterior side faces of the front end sections of the flat-type conductors C1, C2.

An electrical connector assembly includes an electrically conductive structure having a flat flexible conductor that supports a plurality of electrically conductive traces. A wire contact wedge includes a base having an opening extending therethrough and first and second wedge arms that extend from the base. The electrically conductive structure extends through the opening of the base and between the first and second wedge arms. A connector housing supports the wire contact wedge and the electrically conductive structure. The connector housing includes a body having an abutment surface that engages a corresponding abutment surface of the base of the wire contact wedge. A front cover is supported on the connector housing and includes a retaining arm that cooperates with a corresponding protrusion provided on the wire contact wedge.

An electrical connector includes an insulating housing, at least one transmission module mounted in the insulating housing, and a shell surrounding the insulating housing. The at least one transmission module includes a terminal assembly, a flexible printed circuit board and at least one pad. The terminal assembly is adhered to the flexible printed circuit board. The terminal assembly has at least one terminal which has a fastening portion. One end of the fastening portion is arched downward to form a bending portion. The flexible printed circuit board has a linking portion, and at least one conductive piece disposed to an inner surface of the linking portion. The fastening portion and the bending portion of the at least one terminal are mounted to the flexible printed circuit board. The at least one pad is disposed to the at least one conductive piece.

Described herein are circuit assemblies comprising flexible interconnect circuits and/or other components connected to these circuits. In some examples, conductive elements of different circuits are connected with support structures, such as rivets. Furthermore, conductive elements of the same circuit can be interconnected. In some examples, a conductive element of a circuit is connected to a printed circuit board (or other devices) using a conductor-joining structure. Interconnecting different circuits involves stacking these circuits such that the conductive element in one circuit overlaps with the conductive element in another circuit. A support structure protrudes through both conductive elements and any other components positioned in between, such as dielectric and/or adhesive layers. This structure electrically connects the conductive elements and also compresses the conductive elements toward each other. For example, a rivet is used with the rivet heads contacting one or two conductive elements, e.g., directly interfacing their outer-facing sides.