A receptacle connector with a cable-clamped structure of the invention includes a housing, an electrical module and a cable clamping module. The electrical module is disposed in the housing and includes a circuit board, a plurality of contacting terminals and a plurality of prick type terminals. The circuit board is disposed in the housing. The contacting terminals and the prick type terminals are disposed on the printed circuit board. The cable clamping module includes a first clamping member, a second clamping member and a cable clamper, wherein the first clamping member engages the second clamping member, and the cable clamper is pivoted to the first clamping member. A cable extends through the first clamping member and the second clamping member engaging the first clamping member, the cable clamper presses the cable with the first positioning portion positioned in the second positioning portion of the first clamping portion.

A receptacle connector with a cable-clamped structure of the invention includes a housing, an electrical module and a cable clamping module. The electrical module is disposed in the housing and includes a circuit board, a plurality of contacting terminals and a plurality of prick type terminals. The circuit board is disposed in the housing. The contacting terminals and the prick type terminals are disposed on the printed circuit board. The cable clamping module includes a first clamping member, a second clamping member and a cable clamper, wherein the first clamping member engages the second clamping member, and the cable clamper is pivoted to the first clamping member. A cable extends through the first clamping member and the second clamping member engaging the first clamping member, the cable clamper presses the cable with the first positioning portion positioned in the second positioning portion of the first clamping portion.

A retention clip providing mechanical strain relief of a cable in a connector comprises two curved spring sections each having a free end and a base, the two curved spring sections separated from each other at their respective free ends by a cable insertion gap. A center section of the retention cable extends from the base of one of the two curved spring sections to the base of the other one of the two curved spring sections and includes a cable insertion opening. The cable insertion gap and the cable insertion opening are aligned providing a through-opening extending through the retention clip in a cable insertion direction, and each of the free ends has at least one discontinuity in a direction along its edge.

An electrical plug includes an inner housing slidably received within an outer housing. The inner housing includes corrugations at an end of the inner housing to prevent an electrical cable from pulling out of the plug. The inner housing also includes a protrusion that is structured to be received in an aperture of the outer housing to couple the inner housing and the outer housing and provide a visual indicator of proper assembly. The electrical plug further includes fuse clips that increase the contact area between terminals and fuses of the plug, which improves reliability.

A terminal 12 to be connected to a front end part of a wire 11 in an extending direction is provided with a terminal body 15 including a wire connecting portion 20 to be connected to the wire 11, and a shell to be externally fit to the wire connecting portion 20. The wire connecting portion 20 includes a sandwiching portion 18A, 18B extending in the extending direction of the wire 11 and configured to sandwich the wire 11. The shell includes a resilient pressurizing portion for resiliently pressurizing the sandwiching portion 18A, 18B toward the wire 11.

A modular high speed, high density electrical connector configurable for use in multiple configurations, including a direct attach orthogonal configuration. The connector is assembled with modules that include shielded pairs of signal conductors with mating ends that are rotated approximately 45 degrees with respect to intermediate portions of the signal conductors. The connector may have a mating interface with receptacles in one connector and pins in the mating connector. The pins may be small diameter and may be implemented with superelastic wires so as to resist damage despite having very small effective diameter. A compact mating interface resulting from small diameter mating contact portions may enable other portions of the connector, including the shielding surrounding the signal conductors to be smaller, which may raise the resonant frequency of the connector and extend its bandwidth.

A modular high speed, high density electrical connector configurable for use in multiple configurations, including a direct attach orthogonal configuration. The connector is assembled with modules that include shielded pairs of signal conductors with mating ends that are rotated approximately 45 degrees with respect to intermediate portions of the signal conductors. The connector may have a mating interface with receptacles in one connector and pins in the mating connector. The pins may be small diameter and may be implemented with superelastic wires so as to resist damage despite having very small effective diameter. A compact mating interface resulting from small diameter mating contact portions may enable other portions of the connector, including the shielding surrounding the signal conductors to be smaller, which may raise the resonant frequency of the connector and extend its bandwidth.

A connector is configured to terminate an end of a coaxial cable. The connector includes a body, a nut, an outer conductor engager, and a grounding member. The body has a cable receiving end configured to receive the end of the coaxial cable, and the nut is configured to be coupled with and to rotate relative to the body. The outer conductor engager is configured to receive a conductive layer of end of the coaxial cable, and the grounding member is configured to couple the body, the nut, and the outer conductor engager in an assembled configuration. A first end of the grounding member is configured to extend grounding of the coaxial cable from the outer conductor engager to the nut, and a second end of the grounding member is configured to grip an outer protective jacket of the coaxial cable to prevent removal of the coaxial cable from the connector.

A connector assembly for protecting electrical connections in a hazardous environment is provided. The connector assembly includes a first connector, a plug casting, and an elongated mesh grip. The plug casting circumscribes and is secured onto the first connector. The elongated mesh grip is coupled to the plug casting, the mesh grip including a mesh sized to surround the electrical cable, the mesh including a first end and a second end. The mesh has a diameter that is a transverse diameter of a channel defined by the mesh and configured to receive an electrical cable therethrough, wherein the diameter of the mesh decreases when one of the first and second ends of the mesh is pulled away from the other of the first and second ends of the mesh.

A retention clip providing mechanical strain relief of a cable in a connector comprises two curved spring sections each having a free end and a base, the two curved spring sections separated from each other at their respective free ends by a cable insertion gap. A center section of the retention cable extends from the base of one of the two curved spring sections to the base of the other one of the two curved spring sections and includes a cable insertion opening. The cable insertion gap and the cable insertion opening are aligned providing a through-opening extending through the retention clip in a cable insertion direction, and each of the free ends has at least one discontinuity in a direction along its edge.