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.

A connection element for an electronic component assembly includes a support, a first contact pad, and a second contact pad. The first contact pad and the second contact pad are electrically connected. A first contact conductor has a first conductor surface electrically connected to the first contact pad at a first section, and is configured to form a welded connection in a second section of the first conductor surface, and/or on the second conductor surface. The invention also relates to an electronic component assembly which includes such a connection element, and which has at least one component welded to the contact conductor.

A connector includes a pushing member having a projection, a support member disposed to contact a lateral surface of the projection, and a contact made of a conductive material and having a support member facing portion facing the support member, a part of the flexible conductor being disposed between the support member and the support member facing portion of the contact, the lateral surface of the projection pressing the part of the flexible conductor against the support member facing portion of the contact via the support member, whereby the contact is electrically connected to the flexible conductor.

A three-dimensional mounting structure includes a first mounting component, a second mounting component facing the first mounting component, a connecting layer disposed between the first mounting component and the second mounting component, a third mounting component, an adhesive layer, and a barrier sheet. The first mounting component includes a first end surface. The third mounting component is bonded on the first end surface through the adhesive layer. The connecting layer includes a second end surface close to the first end surface. The three-dimensional mounting structure can avoid the adhesive layer overflowing from the first end surface to the second end surface and improve the electronic product yield. A method for assembling the three-dimensional mounting structure is also disclosed.

A composite connector that contributes to an improvement of workability for mating connectors with each other while preventing or reducing an increase in manufacturing cost is provided. A composite connector includes a first module including a first housing in which a first connector is exposed, and a second housing rotatable about the first housing, the second housing including a second connector, and a second module including a third connector, and a third housing including a fourth connector, the third connector being configured to be mated with and connected to the first connector. The composite connector is configured so that the second and fourth connectors are mated with each other in a state in which one of a projection and a recess that is formed in the second housing is mated with the other of the projection and the recess that is formed in the third housing.

A connection terminal for connecting an electrical device to a continuous electrical conductor such as a ground conductor includes a connector body with at least one terminal connection. Each terminal connection includes a recess which extends in a direction of extension of the electrical conductor and a holding device to at least partially close the recess. The holding device is adjustable relative to the direction of extension of the electrical conductor from an open position in which the electrical conductor can be inserted into the recess to a closed position in which the holding device holds the electrical conductor in the recess. The holding device is either reversibly rotatable in a direction of rotation around an axis which extends in the direction of extension or reversibly displaceable in a sliding direction which extends transverse to the direction of extension. The terminal connection includes a clamping means device which clamps the electrical conductor and/or the holding device in the closed position.

An apparatus and method for crosstalk compensation in a jack of a modular communications connector includes a flexible printed circuit board connected to jack contacts and to connections to a network cable. The flexible printed circuit board includes conductive traces arranged as one or more couplings to provide crosstalk compensation.

A terminal assembly includes a multi-wire planar cable having a plurality of flat wires and a common jacket for the plurality of flat wires. The jacket has grooves between adjacent flat wires for controlled separation of the flat wires and surrounding jacket portions at an end of the multi-wire planar cable into separated jacketed wire portions extending a length of the flat wires each including an insulating sleeve and a terminating end of the flat wire. The terminating ends of the flat wires are exposed beyond the insulating sleeves. Terminals are attached to the terminating ends of corresponding flat wires.

Systems, methods, and apparatus are disclosed for implementing power buses. Apparatus may include a first plurality of connectors, a second plurality of connectors, and a first plurality of conductive sheets configured to electrically couple the first plurality of connectors with the second plurality of connectors. The first plurality of conductive sheets may include a first conductive sheet and a second conductive sheet. The first conductive sheet may conduct a first current in a first direction. The second conductive sheet may provide a return path for the first current in a second direction. The apparatus may also include a second plurality of conductive sheets. The second plurality of conductive sheets may include a third conductive sheet and a fourth conductive sheet. The third conductive sheet may conduct a second current in the first direction. The fourth conductive sheet may provide a return path for the second current in the second direction.

A cell contact-making system for an electrochemical device that includes a plurality of electrochemical cells is provided. The cell contact-making system includes a signal conductor system having one or more signal conductors for electrically conductively connecting a signal source to a signal conductor terminal connector or to a monitoring arrangement of the electrochemical device, wherein the signal conductor system includes at least one flexible printed circuit, wherein the flexible printed circuit includes at least one flexible insulating film and at least one conductor track that is arranged on the insulating film.