A fixing structure for an electrical device of the present invention includes: a first operating unit that has a power receiving unit, which receives power feeding from a power feeding unit of a wiring duct, and that engages and disengages the power receiving unit with and from the power feeding unit; a second operating unit that has a second engagement portion, which is supported by a support unit of the wiring duct, and that engages and disengages the second engagement portion with and from the support unit; and a first lock portion that is provided in the first operating unit and locks the second operating unit.

A plug connector housing is provided having at least two oppositely arranged locking pins protruding from the outside, wherein each locking pin includes a metallic component which is overmolded at least in some regions with a plastic material.

A lever-type connector includes a housing configured to rotate about a first shaft, a second lever configured to rotate about a second shaft and a cam groove linked with rotation of the second lever. The first lever includes a guide portion extending from an operating portion toward the first shaft, and the second lever includes a coupling portion coupled to the first lever relatively displaceably along the guide portion. The both levers are linked and rotated between an initial position where connection of the housing and a mating housing is started and a connection position where the connection of the housing and the mating housing is completed. When a virtual line passing through the second shaft and the coupling portion with the second lever located at the initial position is set, the first shaft is located closer to the connection position than the virtual line.

A clamp mechanism for an RF cluster connector enables multiple RF connections within a cluster connector to be engaged and disengaged in such a way that prevents damage to the conductors. It also eases the process of engaging and disengaging through the use of two lever arms that may be easily used by a technician in challenging locations (such as at the top of a cell tower) and in densely arranged RF ports (such as for a multi-user or massive MIMO antenna).

A connector assembly for connecting an upper circuit board to a lower circuit board is disclosed. The upper circuit board includes a series of fastener holes for a fastening device allowing attachment to the lower circuit board. The connector assembly has a support bracket with access holes aligned with the holes of the upper circuit board. The support bracket is configurable to be positioned over the upper circuit board. The connector assembly has a moveable cover bracket having a series of access holes. The cover bracket is suspended between the support bracket and the cover bracket. The cover bracket is moveable between an open position aligning the access holes with the access holes of the support bracket, and a closed position. In the closed position, the cover bracket blocks access between the access holes of the support bracket and the holes of the upper circuit board.

An add-on housing is provided comprising a frame-shaped basic shape which encloses a receiving region for receiving a contact insert or a holding frame fitted with plug-in connector modules, wherein at least two fastening surfaces having fastening openings are integrally formed on the outside of the frame-shaped basic shape, wherein the add-on housing has snap-fastening means or devices which engage through the fastening openings in order to mechanically fasten the add-on housing to a through-hole in a device wall. A method for fastening an add-on housing to a through-hole in a device wall is also provided, wherein: the add-on housing has fastening openings which are in alignment with corresponding fastening openings in the device wall; snap-fastening means or devices having a box-shaped main body and having opposing and resiliently mounted base portions laterally protruding from said main body are inserted into the mutually aligned fastening openings in the add-on housing and the device wall; the base portions, upon insertion into the fastening openings, are first pressed into the box-shaped main body and then extend to engage the device wall.

A system for managing automated charging, the automated charging management system is provided. The system comprises a charging cord management device, a charging cord connector, a power supply, a device, a first charging cord, and a second charging cord. The charging cord management device is configured to locate the power supply. The charging cord management device is configured to align the second charging cord and the charging cord connector with the power supply. The charging cord connector is configured to be in contact with the power supply without user interaction.

An electrical connector assembly includes a cable connector equipped with a locking device essentially composed of an operation part pivotally mounted to the case, and a locking part pivotally mounted to the operation part, and a host connector equipped with a locking ear for locking with the locking part wherein the host connector forms a forward protrusion to form an outer region and an inner region each provided with a sealing member adapted to be compressed in the front-to-back direction by locking mechanism.

The present disclosure provides a connector assembly. The connector assembly includes a connector housing adapted to engage with a corresponding counter-connector housing. A lever including a first lever arm and a second lever arm is pivotably and sealingly mounted to the connector housing. Each lever arm includes interlocking means for connecting the first lever arm to the second lever arm at a first location. The interlocking means of each of the first lever arm and the second lever arm are configured to define complementary symmetrical surfaces that interlock with one another when the lever arms are pivotably mounted to the connector housing. On mounting the lever arms to the connector housing, the lever is configured to move about the connector housing between an open state and a closed state to secure the counter-connector housing to the connector housing.

This lever-type connector comprises a first part forming a base and a second part mobile in relation to the base, the first and second parts inwardly receiving first and second contact assemblies facing one another, male and female respectfully, each provided at one end with conductors to be connected, and a cam mechanism able to move the mobile part between contact disconnection and connection positions. The cam mechanism includes a lever shaped so as to be circumscribed inside the main cross-section of the connector.