A shielded connector structure includes a shielded wire for connecting a device, a shielded connector, and a metal member provided on the device. The shielded connector includes a terminal fitting, a shield terminal, a housing, and a bolt for fixing the housing to the metal member. The metal member includes a circular insertion hole and a female screw portion. The circular insertion hole includes an inner circumferential projected portion and a cutout portion that divides a part of the inner circumferential projected portion. The housing includes a cylindrical housing main body and a fixing flange portion. The housing main body includes a main body insertion portion inserted into the circular insertion hole and a projection portion which protrudes from an outer circumferential surface of the main body insertion portion in conformity with a position of the inner circumferential projected portion.

An electrical device includes a circuit board having upper signal contacts and at least one upper ground contact along an upper surface of the circuit board. The electrical device also includes a communication cable including a differential pair of signal conductors, a shield layer that surrounds the signal conductors, a drain wire electrically coupled with the shield layer, and a cable jacket that surrounds the shield layer and the drain wire. Each of the signal conductors has a wire-terminating end engaged to a corresponding signal contact of the circuit board. The wire-terminating ends project beyond a jacket edge of the cable jacket. An upper ground-terminating component electrically couples to the upper ground contact having a main panel with a connective terminal electrically coupled to the drain wire.

Embodiments of an electrical connector assembly are disclosed. The electrical connector assembly can include an electrical connector having a connector housing and a leadframe supported by the connector housing. The leadframe includes an electrically conductive ground plate that includes a drain wire connection tabs that can attach to drain wires of respective electrical cables. The electrical connector assembly can further include a cable clip that supports the plurality of cables. The electrical connector assembly can further include a cable guide that directs the plurality of cables of cables through the cable clip along a desired direction.

A connector system includes a housing with a paddle card. One side of the paddle card includes a plurality of rows of signal terminations. Another side of the paddle card includes a single row of cable terminations. Cable management members may be used to support the rows of signal terminations. A shield member may be used to improve the electrical performance of the signal terminations.

A safe grounding apparatus (SGA) for safely grounding or neutralizing the electrical conductors for permanent magnet motor (PMM) powered artificial lift systems and methods of practicing the same are disclosed. The SGA of the present invention ameliorates some of the dangers associated with PMM's. Methods of shorting, grounding, testing and monitoring the electrical conductors of a permanent magnet motor in order to safely manipulate the conductors are also disclosed.

A connector and a connector assembly for electrically connecting an electrical cable to a circuit board is described. The connector includes an insulative housing and a plurality of self-supporting terminals. Each of the self-supporting terminal has a retaining portion retained in a corresponding receiving through hole disposed through the housing, a contact portion extending from an upper end of, and perpendicular to the retaining portion such that the contact portion is disposed on an upper surface of the housing and a press-fit portion extending from a lower end of, and substantially parallel to the retaining portion, wherein the press-fit portion extends down from the lower surface of the housing. The connector electrically and physically connecting a conductive wire of an electrical cable with a conductive via of a circuit board by inserting each press-fit portion of the self-supporting terminals into said conductive via.

In an electronic device having a compact form factor, such as a head mounted display (HMD) device, a space-saving harness using bundled or ribbonized strands of micro-coaxial (micro-coax) cable may be utilized to provide signal and/or power interconnects between EMI-generating peripheral components and other components in the device such as those populated on circuit boards. Discrete wires are included in the harness to provide shielding to adjacent micro-coax conductors which may carry high speed signals such as MIPI (Mobile Industry Processor Interface) differential signal pairs and provide power and ground return paths. The discrete wires are subjected to fabrication processes during assembly of the micro-coax harness so that their outer diameters substantially match that of components in the micro-coax cable to thereby facilitate connectorization or termination to the circuit boards and/or other components in the device. The matching outer diameters can also provide a consistent pitch (i.e., spacing between adjacent micro-coax cables and discrete wires) that may facilitate space-saving geometries for the harness, connector, and/or terminations.

A safe grounding apparatus (SGA) for safely grounding or neutralizing the electrical conductors for permanent magnet motor (PMM) powered artificial lift systems and methods of practicing the same are disclosed. The SGA of the present invention ameliorates some of the dangers associated with PMM's. Methods of shorting, grounding, testing and monitoring the electrical conductors of a permanent magnet motor in order to safely manipulate the conductors are also disclosed.

A plurality of electronic wires are fixed by a mold part in a state arranged in at least two rows. The mold part has a first end face from which the electronic wires of a first row in the plurality of electronic wires protrude and a second end face from which the electronic wires of a second row in the plurality of electronic wires protrude. An angle of the first end face with respect to a direction of a central axis line of a multi-core cable differs from an angle of the second end face with respect to the direction of the central axis line. The electronic wires of the first row in the first end face protrude along a direction away from the electronic wires of the second row protruding from the second end face.

A connector is attachable to a front end of a cable in a front-rear direction. The cable comprises coated signal cables and an outer member which protects the signal cables. The connector comprises terminals, a holding member, a shell, an assigned portion and an impedance adjusting portion. The terminals are attached to the signal cables, respectively, under an attached state where the connector is attached to the front end of the cable. The holding member holds the terminals. The shell covers the holding member to have a predetermined surface which intersects with a perpendicular direction perpendicular to the front-rear direction. The assigned portion is located on the outer member of the cable under the attached state. The impedance adjusting portion is located forward of the assigned portion in the front-rear direction and located inward in the perpendicular direction in comparison with both the predetermined surface and the assigned portion.