A Peripheral Component Interconnect Express/Serial Attached SCSI (PSAS) female connector includes a frame member, a terminal member, and a cover member; the frame member including a terminal groove disposed in the frame member and a tilt portion disposed in the terminal groove adjacent to a plug end; the terminal member inserted in the frame member and including a Serial Advanced Technology Attachment (SATA) 7 pin terminal, a Serial Attached SCSI (SAS) 40 pin terminal, a 15 Pin signal terminal, a 6 Pin terminal, and a 4 Pin terminal. When the PSAS female connector is engaged with the male connector, the SATA 7 Pin terminal and the SAS 40 Pin terminal are pressed by a terminal of the male connector to be bent toward an outer lateral side of the terminal groove to contact the elastic plate of the cover member. The present invention effectively improves the cross interference during high speed transmission, thereby achieving the Generation 5 performance requirement.

A high-speed connector includes an insulating housing, and a first terminal assembly mounted in the insulating housing. The first terminal assembly includes a plurality of first terminals including a plurality of first grounding terminals, a first base body, and a first shielding plate disposed under the first base body. The plurality of the first terminals are fastened to the first base body. The first shielding plate has a first base plate, a first metal layer and a plurality of first ribs. Several portions of a top surface of the first base plate extend upward to form the plurality of the first ribs. The first metal layer is a pattern with a plurality of pores. Several of the first grounding terminals contact with the first metal layer which is attached to top surfaces of the plurality of the first ribs to form a grounding structure.

Electrical connection system comprising a primary connection device and a secondary connection device, the primary connection device comprising a shielded cap and primary conductive contacts which extend at least partially inside the shielded cap, the secondary connection device comprising a secondary electrical board which has a secondary mass surface, secondary conductive contacts which extend from an installation surface of the secondary electrical board which is surrounded by the secondary mass surface, and a resilient conductive material which is attached to the secondary mass surface, the electrical connection system being arranged so that the primary conductive contacts are electrically connected to the secondary electrical contacts inside the shielded cap and the shielded cap extends on the resilient conductive material by compressing it.

Disclosed herein is a shield wire grounding device of electric equipment, including: an electric equipment wire electrically connected to the electric equipment, covered by a first sheath, and having an end portion exposed to the outside of the first sheath; a shield wire installed outside the first sheath, and covered by a second sheath; an insulating member covering the exposed portion of the electric equipment; and a grounding member covering the shield wire and the insulating member, electrically connected to the shield wire, and grounded to an electric equipment housing.

A device for connecting an electric wiring harness to the rear of an electrical connector, includes two half-shells configured to be assembled and to receive within them at least one cable of the electric wiring harness, a rear clamping nut designed to compress the two half-shells radially around the cable, a longitudinal body designed to hold the two half-shells axially, a front clamping nut designed to hold the longitudinal body around the electrical connector, wherein each one of the two half-shells includes an inner pad made of an elastomeric material, configured to be in contact with the cable, and an outer jacket made of a rigid material, at least partially enveloping the inner pad and configured to be in contact with the rear clamping nut.

A modular electrical connector with separately shielded signal conductor pairs. The connector may be assembled from modules, each containing a pair of signal conductors with surrounding partially or fully conductive material. Modules of different sizes may be assembled into wafers, which are then assembled into a connector. Wafers may include lossy material. In some embodiments, shielding members of two mating connectors may each have compliant members along their distal portions, such that, the shielding members engage at points of contact at multiple locations, some of which are adjacent the mating edge of each of the mating shielding members.

A modular electrical connector with separately shielded signal conductor pairs. The connector may be assembled from modules, each containing a pair of signal conductors with surrounding partially or fully conductive material. Modules of different sizes may be assembled into wafers, which are then assembled into a connector. Wafers may include lossy material. In some embodiments, shielding members of two mating connectors may each have compliant members along their distal portions, such that, the shielding members engage at points of contact at multiple locations, some of which are adjacent the mating edge of each of the mating shielding members.

An electrical connector for high speed signals. The connector has multiple conductive elements that may serve as signal or ground conductors. A member formed with lossy material and conductive compliant members may be inserted in the connector. The conductive compliant members may be aligned with conductive elements of the connector configured as ground conductors. For a connector configured to carry differential signals, the ground conductors may separate pairs of signal conductors. The member may further include a conductive web, embedded within the lossy material, that interconnects the conductive compliant members. For a receptacle connector, the conductive elements may have mating contact portions aligned along opposing surfaces of a cavity. The conductive elements may have contact tails for attachment to a printed circuit board and intermediate portions connecting the mating contact portions and the contact tails. The conductive compliant members may press against the intermediate portions.

An electrical connector for high speed signals. The connector has multiple conductive elements that may serve as signal or ground conductors. A member formed with lossy material and conductive compliant members may be inserted in the connector. The conductive compliant members may be aligned with conductive elements of the connector configured as ground conductors. For a connector configured to carry differential signals, the ground conductors may separate pairs of signal conductors. The member may further include a conductive web, embedded within the lossy material, that interconnects the conductive compliant members. For a receptacle connector, the conductive elements may have mating contact portions aligned along opposing surfaces of a cavity. The conductive elements may have contact tails for attachment to a printed circuit board and intermediate portions connecting the mating contact portions and the contact tails. The conductive compliant members may press against the intermediate portions.

An electrical connector that includes an outer conductive shell that encloses at least one signal contact therein and includes a front end for mating with a mating connector and a back end opposite the front end for electrically connecting to a printed circuit board. A primary ground connection is located inside or outside of the outer conductive shell, the primary ground connection being configured to electrically engage the mating connector with the printed circuit board or coaxial cable. A secondary ground connection is located inside or outside of the outer conductive shell and is configured to electrically engage the mating connector with the printed circuit board or the coaxial cable.