A base member that is a molded part on which pattern wiring is directly formed, includes a projection projecting from a base surface of the base member. The pattern wiring is laid over a top of the projection, and protrusions are molded on both sides of an area at the top of the projection where the pattern wiring passes.

A printed electrical connector design includes two flat patterned thermoplastic plates printed with mechanical registration features that align conductive traces on the two plates of the electrical connector. A top plate is printed with a plurality of raised pedestals and a plurality of metallic traces. A bottom plate is printed with a plurality of recessed channels and a corresponding plurality of metallic traces. The plurality of recessed channels of the bottom plate are configured to mate with the plurality of raised pedestals on the top plate. The pedestals and channels of the top and bottom plates, respectively, serve to align the metallic traces that comprise the electrical connector. The printed electrical connector design allows printed electrical/electronic circuits and/or devices to be manufactured and interfaced with other printed electrical/electronic circuits and/or devices.

A multi-phase busbar can include a first conducting layer, a first conducting pin, a first insulating layer, and a second conducting layer. The first conducting layer can include a sheet metal coated with an electrically insulating material. The first conducting pin can be mounted to the first conducting layer. The first conducting pin can extend in a direction perpendicular to the first conducting layer. The first insulating layer of a rigid insulating material can be arranged on the first conducting layer. The first insulating layer can define an opening through which the first conducting pin projects. The second conducting layer can include a sheet metal coated with an electrically insulating material, the second conducting layer comprising a first pinhole through which the first conducting pin projects and a second conducting pin which extends in a direction parallel to the first conducting pin.

A cable connector assembly includes a plug for mating with a docking connector, a printed circuit board electrically connected to the plug and a cable electrically connected to the connector, the plug includes a plurality of conductive terminals, the cable includes a plurality of high speed signal cores for transmitting high speed signals and low speed signal cores for transmitting low speed signals, wherein the electrical path of the high speed signal cores connected to the corresponding conductive terminals is shorter than the electrical path of the low speed signal cores connected to the corresponding conductive terminals.

An edge launch signal connector (e.g., RF connector) comprises a connector body having a support aperture, and one or more interface surfaces operable to interface with an edge launch connector support portion of a first circuit board. A plurality of ground contact pins can be supported by the connector body and can be arrayed about the support aperture of the connector body, and a signal pin can be supported within the support aperture. In response to the edge launch signal connector engaging a second circuit board, the signal pin interfaces with a signal contact pad of the second circuit board, and the plurality of ground contact pins interface with at least one ground contact pad. A first circuit board assembly can support a plurality of edge launch signal connectors for blind-mate coupling first and second circuit board assemblies together to accommodate for positional tolerances.

A molded electronic device having a flexible film and electrical connection tracks arranged on the film and configured to be connected to conductive elements of a flexible connector, made of elastomer. The device includes a connector support molded onto the film and electrical connection tracks in order to form walls adapted to hold the connector.

A textile electronic device configured to be connected to a conductive zone of a textile, the device including: an electronic circuit; at least a first mechanical and electrical connection means configured to be connected to the conductive zone of a textile; a textile substrate having at least a second electrical connection means, the at least one second electrical connection means being electrically connected to the electronic circuit and to the at least one first mechanical and electrical connection means; and a flexible envelope totally or partially including said electronic circuit, the at least one first mechanical and electrical connection means and the textile substrate, the at least one first mechanical connection means and electric being at least partially accessible through the flexible envelope. Also, a manufacturing method of the textile electronic device.

A plug for connecting to an Internet-of-Things device is provided. The plug has a housing and a printed circuit board with a first and second end. The printed circuit board is provided in the housing. The first end of the printed circuit board is connected to a hybrid single pair Ethernet cable. The second end of the printed circuit board is provided with a plug-in face with contact surfaces, by means of which the plug can be coupled to the Internet-of-Things device. The plug also has an EMC protection unit in or on the printed circuit board.

A multi-phase busbar can include a first conducting layer, a first conducting pin, a first insulating layer, and a second conducting layer. The first conducting layer can include a sheet metal coated with an electrically insulating material. The first conducting pin can be mounted to the first conducting layer. The first conducting pin can extend in a direction perpendicular to the first conducting layer. The first insulating layer of a rigid insulating material can be arranged on the first conducting layer. The first insulating layer can define an opening through which the first conducting pin projects. The second conducting layer can include a sheet metal coated with an electrically insulating material, the second conducting layer comprising a first pinhole through which the first conducting pin projects and a second conducting pin which extends in a direction parallel to the first conducting pin.

An integrated multilayer structure, includes a substrate film having a first side and an opposite second side. The substrate film includes electrically substantially insulating material, a circuit design including a number of electrically conductive areas of electrically conductive material on the first and/or second sides of the substrate film, and a connector including a number of electrically conductive contact elements. The connector is provided to the substrate film so that it extends to both the first and second sides of the substrate film and the number of electrically conductive contact elements connect to one or more of the conductive areas of the circuit design while being further configured to electrically couple to an external connecting element responsive to mating the external connecting element with the connector on the first or second side of or adjacent to the substrate film.