A connection structure of a shielded terminal 10 and a shielded electrical wire 60 includes a shielded electrical wire 60 including a shield layer 63; and a shielded terminal 10 including an outer conductor 20 connected to the shield layer 63, wherein the outer conductor 20 is formed by assembling a first shell 21 including an electrical wire connection portion 30, 31, 32 that comes into contact with an outer circumference of the shield layer 63, and a second shell 22 including a compression bonding portion 44 that is crimped to an outer circumference of the electrical wire connection portion 30, 31, 32, and a catch portion 36 that catches on an outer circumferential surface of the shield layer 63 is formed in the electrical wire connection portion 30, 31, 32.

A connection structure of a shielded terminal 10 and a shielded electrical wire 60 includes a shielded electrical wire 60 including a shield layer 63; and a shielded terminal 10 including an outer conductor 20 connected to the shield layer 63, wherein the outer conductor 20 is formed by assembling a first shell 21 including an electrical wire connection portion 30, 31, 32 that comes into contact with an outer circumference of the shield layer 63, and a second shell 22 including a compression bonding portion 44 that is crimped to an outer circumference of the electrical wire connection portion 30, 31, 32, and a catch portion 36 that catches on an outer circumferential surface of the shield layer 63 is formed in the electrical wire connection portion 30, 31, 32.

A cable assembly includes a plug receiver, a conductor interface, a metal shell encasing the conductor interface and a portion of a cable of the cable assembly, a metal foil that wraps conformably around an exterior of the metal shell, wherein the metal foil covers substantially all of the exterior of the metal shell and extends beyond the metal shell onto a cable shielding layer. The cable assembly further includes a solder layer disposed about the metal foil, wherein the solder layer bonds and electrically couples the first foil portion to itself, the second foil portion to cable shielding at the location on the plurality of conductors that is proximate to the conductor interface, and the third foil portion to the plug receiver. The cable assembly further includes an electrically insulating layer that encases the metal shell, the metal foil, and the solder layer.

A connector structure includes an insulating case, a terminal set and a grounding component. The terminal set is configured in the insulating case. The terminal set further includes a first terminal set, and the first terminal set includes a plurality of signal terminals and a plurality of grounding terminals. The grounding component is configured in the insulating case. The grounding component includes a component body and a graphene layer configured on a surface of the component body. The first grounding terminals are connected in series by contacting the graphene layer.

The present disclosure relates to a board connector comprising a plurality of RF contacts; an insulation unit; a plurality of transmit contacts and a plurality of second RF contacts, so that the first and second RF contacts are spaced apart along a first axial direction; a ground housing; a first ground contact coupled to the insulation unit, and providing shielding between the first RF contacts and the transmit contacts, with respect to the first axial direction; and a second ground contact coupled to the insulation unit, and providing shielding between the second RF contacts and the transmit contacts, with respect to the first axial direction, wherein the first ground contact provides shielding between the first RF contacts and the transmit contacts, with respect to the first axial direction, and provides shielding between the first RF contacts with respect to a second axial direction perpendicular to the first axial direction.

The present disclosure relates to a board connector comprising a plurality of RF contacts; an insulation unit; a plurality of transmit contacts and a plurality of second RF contacts, so that the first and second RF contacts are spaced apart along a first axial direction; a ground housing; a first ground contact coupled to the insulation unit, and providing shielding between the first RF contacts and the transmit contacts, with respect to the first axial direction; and a second ground contact coupled to the insulation unit, and providing shielding between the second RF contacts and the transmit contacts, with respect to the first axial direction, wherein the first ground contact provides shielding between the first RF contacts and the transmit contacts, with respect to the first axial direction, and provides shielding between the first RF contacts with respect to a second axial direction perpendicular to the first axial direction.

An electrical connector includes an insulative housing defining a vertical mating direction, a plurality of contacts secured to the insulative housing, and a metallic shield secured to the insulative housing and surrounding the plurality of contacts, wherein the metallic shield and the plurality of contacts are insert-molded with the insulative housing, and the metallic shield has a pair of substantially vertical side walls, a pair of substantially vertical end walls respectively connected between the pair of side walls, and a pair of bottom walls connected between the pair of side walls.

An electrical connector includes an insulative housing defining a vertical mating direction, a plurality of contacts secured to the insulative housing, and a metallic shield secured to the insulative housing and surrounding the plurality of contacts, wherein the metallic shield and the plurality of contacts are insert-molded with the insulative housing, and the metallic shield has a pair of substantially vertical side walls, a pair of substantially vertical end walls respectively connected between the pair of side walls, and a pair of bottom walls connected between the pair of side walls.

An electrical connector includes an insulating housing, a number of terminals and a lossy member. The terminals include a number of ground terminals and a number of signal terminals. The ground terminals and the signal terminals are set adjacently to each other but do not contact each other. The ground terminals do not directly contact the lossy member. As a result, installation consistency of the ground terminals can be achieved, thereby improving the electrical performance of the electrical connector.

A modular electrical connector with broad-side coupled signal conductors in a right angle intermediate portion. Broadside coupling provides balanced pairs for very high frequency operation. The connector is assembled with multiple subassemblies, each of which has multiple pairs of signal conductors. The subassemblies are formed from an insulative portion having grooves in opposite sides into which the intermediate portions of signal conductors. Covers, holding the signal conductors in the grooves, establish the position of the signal conductors relative to reference conductors at the exterior of subassembly, so as to provide a controlled impedance. Lossy material is positioned between the pairs in a subassembly and/or contacts the reference conductors of the subassemblies, and the lossy material of the subassemblies is in turn connected with a conductive structure.