A power plug device includes a first housing, a circuit board, a wire assembly and a second housing. The first housing includes an upper-housing body, a through hole and an inner cover. An accommodating portion is arranged in the upper-housing body, the through hole is formed on one side of the upper-housing body, the inner cover is installed in the accommodating portion, a receptive space is arranged in the inner cover, and the through hole interconnects with the receptive space. The wire assembly includes core wires, which passes through the through hole and the receptive space, so that the core wires are accommodated in the accommodating portion, and the receptive space is suitable for accommodating glue to secure the core wires and provides waterproof effect. In addition, dual-layered waterproof structure is used to make the first and second housing joining together having stronger waterproof effect.

The present invention discloses a protective cover plate for a flat plug and the flat plug with the same. A limit slot is arranged on a cover plate body of the protective cover plate and is configured to be sheathed outside the flat plug and to limit the flat plug, so that the flat plug is located in a protective space of the cover plate body. The flat plug can be inserted into or pulled from a plugboard by operating the protective cover plate. The flat plug is used in cooperation with the protective cover plate, and a positioning insert matched with the limit slot is arranged on the flat plug, thereby improving the safety of use.

A ganged connector assembly includes: a plurality of coaxial connectors, each of the coaxial connectors connected with a respective coaxial cable extending rearwardly therefrom, each of the coaxial connectors including an inner contact and an outer body that is electrically separated from the inner contact; a shell having a plurality of cavities; and a plurality of rear bodies, each of the rear bodies encircling a respective outer body, each of the rear bodies mounted in a respective cavity of the shell. Each of the rear bodies includes a first locking feature. A second locking feature is located in each of the cavities and is fixed relative to the shell. The first and second locking features are configured such that rotation of a first of the plurality of rear bodies relative to the shell moves the first rear body between locked and unlocked positions, wherein in the locked position a respective first connector and respective first cable are secured with the shell within a respective cavity, and in the unlocked position the first connector and first cable can be removed from the shell without removing the remaining connectors and cables.

An electrical connection device is enabled to be linked materially and electrically to an external support that has an electric potential difference, and at the same time enabled to be linked materially and electrically to an external electrically operated device, and therefore for transmitting electric potential between the external support and the external device, which includes a base that incorporates a spring and a shaft enabled for receiving and transmitting the electric potential difference from the external support and is arranged and enabled on the same base in order to make electrical contact with the support of a compressive force on the spring.

Disclosed herein is a connector assembly for attachment to a corrugated coaxial cable. The assembly includes: a rearward outer body, to be received over a portion of the corrugated coaxial cable, comprising a recessed area; and a locking ferrule, to be inserted into the rearward outer body, comprising a plurality of ridges. At least one of the plurality of ridges is configured for engagement with the corrugated outer conductor. The connector assembly further comprises a foot portion positionable within the recessed area such that upon coupling of the rearward outer body with the locking ferrule, the corrugated outer conductor is locked in position.

An electrical connector that connects circuit boards in a coplanar manner. The electrical connector includes a frame comprising a plate, and two platforms extending above the plate and substantially parallel to each other. A housing of the electrical connector holding conductive elements is coupled to the plate of the frame such that a top surface of the housing is substantially flush with top surfaces of the two platforms. The platforms of the frame have threaded holes extending therethrough such that screws can be inserted to hold one of the two platforms of the electrical connector to a first circuit board and the other one of the two platforms of the electrical connector to a second circuit board that is substantially edge aligned to the first circuit board. Such a configuration enables connecting circuit boards of various thicknesses in a coplanar manner.

A heat dissipating hardline connector includes a first body portion configured to support a terminal pin assembly and a second body portion configured to be coupled with the first body portion. The second body portion is configured to receive a hardline cable. The second body portion includes a plurality of spaced apart annular grooves formed in an outer surface of the second body portion to define a plurality of fin portions that are spaced apart from one another along a length of the second body portion. The annular grooves and fin portions are configured to increase the surface area of the outer surface of the second body portion to provide increased heat dissipation by the second body portion.

A power distribution assembly with boltless busbar system for electrically and mechanically connecting a component to a power source is disclosed. The power distribution assembly includes an interconnecting busbar segment that connects two boltless busbar system together. Each boltless busbar system includes a male busbar assembly and a female busbar assembly. The male busbar assembly includes a male terminal, internal spring member, internal male housing, and external male housing that receives an extent of the male terminal, the internal spring member, and the internal male housing. This male terminal includes a side wall arrangement that defines a receiver and further includes at least one contact arm. An internal spring member with at least one spring arm resides within the male terminal receiver. The female busbar assembly includes a female terminal with a receptacle that is dimensioned to receive both the male terminal and the spring member in a connected position to secure the female busbar assembly to the male busbar assembly.

A connector includes a body having a central bore and a first grounding contact surface, a post disposed within the central bore and having an outwardly projecting flange configured to produce a first portion of a mating interface, and a conductive coupler. The post portion has a tubular sleeve configured to mechanically and electrically engage a prepared end of a coaxial cable. The conductive coupler has an engagement surface at a first end configured to mechanically and electrically engage an interface port, a lip at a second end configured to produce a second portion of the mating interface, and a second grounding contact surface opposing the first grounding contact surface. The first and second portions are configured to slide along the mating interface to rotate about an elongate axis of the connector. The connector includes a conductive ring disposed between the first and second grounding contact surfaces and configured to produce an electrical path between the body and the conductive coupler.

A high frequency (HF) terminal for an HF connector includes an electromechanical contact section, a mechanical fastening section, an electromechanical connection section, and an HF compensation region apart from the electromechanical contact section. The HF compensation region is geometrically developed in such a way that a loss in a signal integrity of an HF plug-in connector including the HF connector with the HF terminal and an HF mating connector with an HF mating terminal in a final plugged-in position can be at least partially compensated by the HF compensation region.