A plug connector housing for a plug connector, having a main body and a latching installation. The latching installation has a first connection portion integrally connecting the latching mechanism to the main body. A void extends along a longitudinal axis on the main body and is at least in portions formed between the latching installation and the main body. The plug connector housing furthermore has first and second protective elements which extend in each case integrally from the main body. The latching installation is disposed between the protective elements, wherein each of the protective elements in at least one covered region covers the void in a transverse direction. Each of the protective elements moreover configures at least one access region in which the void is accessible along the transverse direction. Each of the covered regions faces a respective access region of the respective other protective element along the transverse direction.

A method for making a bayonet connecting element for a connector, according to which a connecting element body, with a hollow cylindrical general shape is made. The method includes making a through bore by drilling a wall of the body of the connecting element, from the outer surface of the wall. The outer surface of the wall is machined around the bore so as to create a conical contact surface around the bore. A lug is inserted into the bore, from the outer surface of the wall, so that a head of the lug projects from the outer surface of the wall of the connecting element. The lug having a conical contact surface corresponding to the conical contact surface of the bore.

Electrical connectors for very high speed signals, including signals at frequencies at or above 112 GHz, with high density. Such connectors may be formed with fine features molded into portions of the connector housing to support closely spaced signal conductors. The signal conducts may nonetheless be accurately positioned, which leads to uniform impedance and other electrical characteristics that enable high frequency operation through the use of skeletal members that restrain bowing and twisting of housing components that position, directly or indirectly, the signal conductors. The skeletal members may be simply incorporated into the housing components by stamping a metal skeleton from a metal sheet in conjunction with one or more carrier strips. The housing component may be overmolded around the skeleton and then severed from the carrier strips.

Electrical connectors for very high speed signals, including signals at frequencies at or above 112 GHz, with high density. Such connectors may be formed with fine features molded into portions of the connector housing to support closely spaced signal conductors. The signal conducts may nonetheless be accurately positioned, which leads to uniform impedance and other electrical characteristics that enable high frequency operation through the use of skeletal members that restrain bowing and twisting of housing components that position, directly or indirectly, the signal conductors. The skeletal members may be simply incorporated into the housing components by stamping a metal skeleton from a metal sheet in conjunction with one or more carrier strips. The housing component may be overmolded around the skeleton and then severed from the carrier strips.

A harness comprises a connector body, a cable and a cable-holding portion which holds the cable. The connector body comprises a base portion. The cable is connected to the connector body. The cable has an end portion received in the base portion and a main portion extending rearward from the end portion. The cable-holding portion is formed with a recessed portion which opens at least downward in the upper-lower direction (Z-direction). The base portion has an interference portion. The recessed portion and the interference portion are located at opposite sides of the harness, respectively, in the lateral direction (Y-direction). The recessed portion is, at least in part, located at a position same as that of the interference portion in the front-rear direction (X-direction). The recessed portion is, at least in part, located at a position same as that of the interference portion in the upper-lower direction.

An electrical connector having a first connector part and a second connector part, the first connector part with at least one electrically conductive pin and the second connector part with at least one shuttle pin, the conductive pin having two or more electrically conductive cores, each conductive core being provided with an external electrical contact and an insulating material forming a watertight seal with the conductive core and the electrical contact. The conductive cores include two or more cores spaced from one another to form the conductive pin. Facing surfaces of the two or more cores are spaced by an air gap with insulating material in the air gap and overmoulded insulating material is in contact with other surfaces of the conductive cores.

An electrical connector having a first connector part and a second connector part, the first connector part with at least one electrically conductive pin and the second connector part with at least one shuttle pin, the conductive pin having two or more electrically conductive cores, each conductive core being provided with an external electrical contact and an insulating material forming a watertight seal with the conductive core and the electrical contact. The conductive cores include two or more cores spaced from one another to form the conductive pin. Facing surfaces of the two or more cores are spaced by an air gap with insulating material in the air gap and overmoulded insulating material is in contact with other surfaces of the conductive cores.

There is described a method for assembling a connectorized electrical equipment. A connectivity list required for the connectorized electrical equipment is provided, comprising an origin connector and its identifier, a destination electrical equipment subpart and its identifier thereof; and a list of connections between the origin connector and the destination electrical equipment subpart. By querying a database comprising a library of connectors, a construction plan is generated for the connectorized electrical equipment. The construction plan includes diagrams for assembly, images to assist the assembler, a list of material for managing inventory and instructions. An ATE can be connected to the connectorized electrical equipment to be assembled. Based on the construction plan, instructions are provided for a connection between the origin connector and the destination electrical equipment subpart. Connections can be made manually or using the ATE. All connections are registered in real time for progression tracking and instruction updates.

There is described a method for assembling a connectorized electrical equipment. A connectivity list required for the connectorized electrical equipment is provided, comprising an origin connector and its identifier, a destination electrical equipment subpart and its identifier thereof; and a list of connections between the origin connector and the destination electrical equipment subpart. By querying a database comprising a library of connectors, a construction plan is generated for the connectorized electrical equipment. The construction plan includes diagrams for assembly, images to assist the assembler, a list of material for managing inventory and instructions. An ATE can be connected to the connectorized electrical equipment to be assembled. Based on the construction plan, instructions are provided for a connection between the origin connector and the destination electrical equipment subpart. Connections can be made manually or using the ATE. All connections are registered in real time for progression tracking and instruction updates.

A semiconductor device includes: a plate-shaped terminal including one main surface and another main surface and having one end electrically connected to a semiconductor chip; a nut arranged on the one main surface side at another end of the terminal; a nut cover provided on the one main surface side at the other end of the terminal and configured to cover the nut; and a case configured to surround the semiconductor chip and integrate the terminal and the nut cover, wherein the nut cover includes a protruding portion protruding from a lower portion of the nut cover to the one end side of the terminal.