A electrical connector (100) includes an insulative housing (1), a number of terminals (2), a stiffener (3) and a pair of insulative members (4). The insulative housing includes a tongue portion (11) defining a number of first passageways (111a) and two molding holes (115a, 115b) communicating with the first passageways for accommodating a number of molds. The stiffener is insert molded with the insulative housing and defines two openings (33a, 33b) communicating with the molding holes. The insulative members cover the openings for sealing the molding holes after removal of the molds.

A micro plug connector has an insulative housing with multiple mounting holes, multiple terminals respectively mounted in the mounting holes, and a shielding shell covering the insulative housing and the terminals. Each terminal has a mounting section mounted in the insulative housing, a welding section protruding backward from a rear end of the mounting section and protruding out of a rear portion of the insulative housing, and an electrical connection section protruding forward from a front end of the mounting section and partially exposed out of a corresponding one of the mounting holes. Each of at least one of the terminals has an anti-bending protrusion abutting against an inner top surface defined in the corresponding one of the mounting holes. The anti-bending protrusion prevents a distal end of the electrical connection section of the terminal from bending up and contacting the shielding shell by accident.

An electrical connector includes: an insulative housing having a base portion; a number of conductive terminals affixed to the insulative housing and arranged in two rows, each conductive terminal comprising a contacting portion, and each row of conductive terminals comprising a pair of grounding terminals and a number of internal terminals located between the pair of grounding terminals; a metal shielding plate affixed to the insulative housing and sandwiched between the two rows of conductive terminals; and a main shell enclosing the insulative housing; wherein a distance between the contacting portions of the internal terminals and the metal shielding plate is greater than a distance between the contacting portions of the grounding terminals and the metal shielding plate.

A connector assembly includes a metal shielding cage. The metal shielding cage includes a cage body, a back cover and a grounding member. The cage body has a top wall, a mounting side and two side walls, the top wall, the mounting side and the two side walls together define a receiving space extending along a front-rear direction, the receiving space has a front opening toward the front and a rear opening positioned at the rear, the back cover and the grounding member are assembled at the rear opening of the cage body, and the grounding member is provided with an elastic grounding finger row toward the mounting side.

A connector assembly includes a guide shielding cage, an internal biasing heat sink and two lateral heat dissipating members. The guide shielding cage includes a cage body and a partitioning bracket provided in the cage body, the cage body has a top wall and two side walls, the partitioning bracket has an upper wall and a lower wall which together define an interior receiving space, and the partitioning bracket and the cage body together define an upper receiving space and a lower receiving space, each side wall of the cage body is formed with a side window which is communicated with the interior receiving space, the lower wall of the partitioning bracket is formed with a lower window which allows the interior receiving space to be communicated with the lower receiving space. The internal biasing heat sink is provided in the partitioning bracket and has an internal heat dissipating member, the internal heat dissipating member enters into the lower receiving space via the lower window. The two lateral heat dissipating members are respectively positioned outside the two side walls of the cage body, the two lateral heat dissipating members and the internal heat dissipating member are connected with each other by means of connecting structures which respectively pass through the side windows, the two lateral heat dissipating members is capable of moving with the internal heat dissipating member along the up-down direction.

A connector cage includes a bezel, having a plurality of slots formed therein, and a cage structure including upper and lower sides and multiple partitions extending between the upper and lower sides to define receptacles for receiving cable connectors. Multiple tabs protrude out of at least one of the sides in locations at which the tabs fit into the slots in the bezel, and are folded over the slots so as to secure the cage structure to the bezel. The cage may also include multiple snap-on spring subassemblies, each spring subassembly secured to a front end of a respective partition and comprising leaves that bow outward to contact the shells of the connectors that are inserted into the receptacles adjacent to the partition.

A connector cage includes a bezel, having a plurality of slots formed therein, and a cage structure including upper and lower sides and multiple partitions extending between the upper and lower sides to define receptacles for receiving cable connectors. Multiple tabs protrude out of at least one of the sides in locations at which the tabs fit into the slots in the bezel, and are folded over the slots so as to secure the cage structure to the bezel. The cage may also include multiple snap-on spring subassemblies, each spring subassembly secured to a front end of a respective partition and comprising leaves that bow outward to contact the shells of the connectors that are inserted into the receptacles adjacent to the partition.

The embodiments of the present invention provide a shielded connector having improved shielding effectiveness to reduce electromagnetic interference (EMI). Some of the various embodiments provide high-speed electrical connectors capable of carrying gigabyte data rate signals. The shielding may employ, among other things, one or more shielding structures to reduce the EMI associated with these and other signals. The shielding structures may be oriented to reduce or limit the apertures within the connector through which EMI can penetrate. For example, some embodiments for a universal serial bus (USB) connector may support both a USB 3.0 and USB 2.0. For these embodiments, a grounding tab or peg may be placed in the rear of the connector between the USB 3.0 and the USB 2.0 connections to divide the aperture for the port into a plurality of sections. The grounding tab or peg may also serve as a structural support for the connector.

The embodiments of the present invention provide a shielded connector having improved shielding effectiveness to reduce electromagnetic interference (EMI). Some of the various embodiments provide high-speed electrical connectors capable of carrying gigabyte data rate signals. The shielding may employ, among other things, one or more shielding structures to reduce the EMI associated with these and other signals. The shielding structures may be oriented to reduce or limit the apertures within the connector through which EMI can penetrate. For example, some embodiments for a universal serial bus (USB) connector may support both a USB 3.0 and USB 2.0. For these embodiments, a grounding tab or peg may be placed in the rear of the connector between the USB 3.0 and the USB 2.0 connections to divide the aperture for the port into a plurality of sections. The grounding tab or peg may also serve as a structural support for the connector.

A connector includes a housing, an outer shield including a tubular portion, and a terminal surrounded by the tubular portion of the outer shield. The connector is connected to a mating connector by moving toward the mating connector in a predetermined direction relatively with respect to the mating connector. A first end of the tubular portion of the outer shield is located in the predetermined direction in the tubular portion. The tubular portion of the outer shield has an inner circumferential surface facing a hollow space, an outer circumferential surface opposite to the inner circumferential surface, and a distal end surface provided at the first end. At least one of the distal end surface, the outer circumferential surface, and the inner circumferential surface is seamless over an entire circumference of the tubular portion surrounding the hollow space along a circumferential direction of the tubular portion.