This shield connector is provided with an inner conductor (15), a dielectric body (19) that accommodates the inner conductor (15), and an outer conductor (18) that encloses the dielectric body (19). The dielectric body (19) comprises a stopper section (34) that abuts the outer conductor (18) and stops movement of the dielectric body (19) along a wall surface of the outer conductor (18). Positional offset of the dielectric body (19) with respect to the outer conductor (18) can be prevented due to the stopper section (34) abutting the outer conductor (18).

A connector includes a first shell, a second shell, a tongue plate and a number of conductive pads. The first shell includes a first protruding piece extending along a first direction. The second shell includes a second protruding piece extending along the first direction. The tongue plate is located between the first protruding piece and the second protruding piece in a second direction. The tongue plate includes a mating surface. The plurality of conductive pads are provided on the tongue plate and exposed to the mating surface. The first protruding piece has a first width in a third direction perpendicular to the first direction and the second direction. The second protruding piece has a second width along the third direction. The first width is the same as the second width. As a result, the connector is easy to manufacture, thereby reducing the cost of the connector.

A connector assembly includes a housing with a terminal cavity and a terminal lock adapted to retain an electrical terminal in the terminal cavity. A terminal position assurance is attached to the housing and engages the terminal lock. The connector assembly also includes a protector plate with a protector body having a front plate face and an opposed back plate face. Terminal openings pass through the protector body. A plurality of staged locks are attached to the protector body for relative rotational movement. The staged locks extending beyond the front plate face and also extending beyond the back plate face. The protector plate is movable relative to the housing in a mate direction from a pre-stage position to a pre-lock position. The protector plate is retained in the pre-lock position relative to the housing against further movement in the mate direction by a staged lock.

The invention relates to a direct plug-in connector (1) for establishing an electric connection between a conductor (30) and a metallized through opening (40) of a printed circuit board (50). The direct plug-in connector (1) has a fastening element (4) and a contact (2) with at least one first contact arm (3a). The first contact arm (3a) is configured for the electric connection of the conductor (30) to the metallized through opening (40). The fastening element (4) can assume a fastening position and a release position, the fastening element (4) being configured to fasten the direct plug-in connector (1) to the metallized through opening (40) in the fastening position.

The invention relates to a direct plug-in connector (1) for establishing an electric connection between a conductor (30) and a metallized through opening (40) of a printed circuit board (50). The direct plug-in connector (1) has a fastening element (4) and a contact (2) with at least one first contact arm (3a). The first contact arm (3a) is configured for the electric connection of the conductor (30) to the metallized through opening (40). The fastening element (4) can assume a fastening position and a release position, the fastening element (4) being configured to fasten the direct plug-in connector (1) to the metallized through opening (40) in the fastening position.

An electrical power connector and an electrically conductive terminal are provided. The electrical power connector includes an insulating housing, multiple electrically conductive terminals, and at least one position fixing member. The insulating housing includes multiple column bodies and a convex rib structure, the column bodies extend in a first direction and are arranged at intervals, and the convex rib structure extends in a second direction and is formed in an intersecting arrangement. An inside of the insulating housing has multiple tunnels that correspondingly penetrate through the column bodies in the first direction. Multiple grid passages are formed by the convex rib structure. The electrically conductive terminals are respectively mated in the grid passages and the tunnels. The electrically conductive terminals are each connected to a cable. The at least one position fixing member is embedded on at least one side of the convex rib structure.

A split housing connector assembly provides integrated terminal position assurance and an independent secondary lock and includes a nosepiece and a rear housing. In a pre-lock configuration, a plurality of wire terminal bays are aligned to allow insertion of wire terminals and wherein in a locked configuration the rear housing is displaced relative to the nosepiece offsetting the wire terminal bays and blocking removal of the wire terminals. The rear housing engages the nosepiece along a cam track to guide relative movement during assembly.

A connector configured to provide signal and power connections reliably and economically in a compact space. The connector may include terminals each comprising a mating portion and a mounting portion opposite the mating portion. The terminals may be arranged with multiple rows of signal terminals and power terminals aligned in one row and on opposite sides of the signal rows. The mounting portions of the terminals may be configured to receive cables in some embodiments, and mount to a board in some other embodiments.

A connector configured to provide signal and power connections reliably and economically in a compact space. The connector may include terminals each comprising a mating portion and a mounting portion opposite the mating portion. The terminals may be arranged with multiple rows of signal terminals and power terminals aligned in one row and on opposite sides of the signal rows. The mounting portions of the terminals may be configured to receive cables in some embodiments, and mount to a board in some other embodiments.

An electrical female terminal for mating with a connector assembly generally including a main body, a two-bodied spring, and a wire fastening portion. A protrusion extends from an unattached end portion of the lever member, the protrusion having faces angled relative to each other to efficiently deflect the lever member upwards when the protrusion interacts with an internal protrusion of a housing or a connector assembly. A top portion of the retainer member of the electrical female terminal, located above the two-bodied spring, has a dimple portion. The terminal face or leading end portion of the electrical female terminal is prevented from damaging or cutting a silicone seal. The overstress feature of the tang member of the lever is improved upon by relocating and reshaping the protruding member thereof. The configuration or shape of the cross-section across the upper portion and the support member at the front end portion of the main body of the electrical female terminal is substantially U-shaped. The configuration or shape of the cross-section across the attached end portion of the lever member of the electrical female terminal is also substantially U-shaped. The electrical female terminal is formed as a continuous and contiguous single construction having included therein at least the main body, the two-bodied spring, and the wire fastening portion and/or the lever member (or tang member), along with the neck member that joins the main body and the wire fastening portion.