An illustrative example embodiment of a connector includes a terminal configured to establish an electrically conductive connection with another component and a shroud surrounding the terminal. The shroud includes a first sidewall and a second sidewall that is transverse to the first sidewall. The first sidewall and the second sidewall have a sidewall dimension in a direction parallel to a longitudinal axis of the terminal. The shroud includes a first transition between the first sidewall and the second sidewall in the form of a hollow cylindrical sector having a first angular measurement of more than 90 degrees. The transition has a transition dimension that is less than the sidewall dimension.

A cell-monitoring connector is configured to be detachably mounted to a fuel cell. A housing configured such that a portion thereof is insertable into a receiving space. A pair of lever operators is configured to be movable by a first external pressure in a third direction that intersects the first direction and the second direction. A number of levers are coupled to the pair of lever operators inside the housing. The levers include latching protrusions configured to operate in connection with movement of the lever operators. The latching protrusions are movable between a first position at which the latching protrusions protrude in the third direction from an outer surface of the housing and a second position at which the latching protrusions do not protrude from the outer surface of the housing.

Prior-art connectors require burdensome operations that involve connecting the male screws of the threaded retaining members mounted on an overmolded connector unit to the internal threads provided in a counterpart connector and tightening the screws by turning in order to prevent connector disengagement. In addition, repeatedly attaching and detaching the connector may create a problem by increasing the burden of such operations.

The present invention provides a connector and a connector device that allows for easy attachment to and detachment from a counterpart connector by providing a locking mechanism that automatically locks upon connection to a counterpart connector and that permits unlocking by depressing buttons in a connector that includes a connector unit provided in a distal end section of a cable and a housing that holds said connector unit inside and is equipped with a locking mechanism for locking to a counterpart connector.

A holder bracket for extension cord receptacle head having a base plate and one or more clips, hooks, claws, or latches for receiving and securing to a surface a receptacle head of an electrical extension cord. The clips, hooks, claws, or latches provide flexibility which allow for easy intentional insertion and removal of the receptacle head of the electrical extension cord, sufficient retention force to allow single-handed plugging and unplugging of electrical plugs into and out of the receptacle head, and a forceful release feature to prevent or reduce trip hazards that may be posed by the electrical extension cord.

A holder bracket for extension cord receptacle head having a base plate and one or more clips, hooks, claws, or latches for receiving and securing to a surface a receptacle head of an electrical extension cord. The clips, hooks, claws, or latches provide flexibility which allow for easy intentional insertion and removal of the receptacle head of the electrical extension cord, sufficient retention force to allow single-handed plugging and unplugging of electrical plugs into and out of the receptacle head, and a forceful release feature to prevent or reduce trip hazards that may be posed by the electrical extension cord.

A high-speed connector for an automobile includes a cable connector, a board connector connected to the cable connector, and sliding blocks provided on two sides of the cable connector. The sliding blocks are separate or are integrated. The cable connector includes a housing, a contact body and a cable. The contact body is installed in the housing. The contact body is in contact with the board connector to achieve an electric connection. The cable is connected to the contact body and protrudes out of the housing. The housing includes a main body portion and side snap-fit plates provided on two sides of the main body portion. A side snap-fit groove is provided on the side snap-fit plate. Side snap-fit clasps are provided on two sides of the board terminal connector. The sliding blocks are installed on the side snap-fit plates and slide upwards and downwards along the side snap-fit plates.

A connector includes a first housing (10) and a second housing (60) connectable to each other. The second housing (60) includes two walls (64) facing each other. The first housing (10) includes a receptacle (12) defining a fitting space (14), two side walls (19) connected to both circumferential ends of the receptacle (12) and a lock arm (24) arranged between the side walls (19). Entrance spaces (29) into which the walls (64) enter are defined between the side walls (19) and the lock arm (24) to communicate with the fitting space (14). Protrusions (31, 32) configured to contact the walls (64) are provided on inner surfaces of the side walls (19).

An electrical connector with biased latch and method. The electrical connector has a housing and a latch which extends from the housing. The latch has a latching region and a biasing region. The latching region has a latching projection with a reference surface. The biasing region has a biasing member. The cooperation of the biasing member with a mating electrical connector and the reference surface with the mating electrical connector prevents the unwanted movement of the electrical connector relative to the mating electrical connector.

An electrical connector with biased latch and method. The electrical connector has a housing and a latch which extends from the housing. The latch has a latching region and a biasing region. The latching region has a latching projection with a reference surface. The biasing region has a biasing member. The cooperation of the biasing member with a mating electrical connector and the reference surface with the mating electrical connector prevents the unwanted movement of the electrical connector relative to the mating electrical connector.

An electrical connector assembly can include a plug connector mountable to a planar substrate and a receptacle connector configured to receive a plurality of cables and that can mate with the plug connector. The plug connector may include a first inline terminal row and a second inline terminal row exposed on a mounting face to conductively contact the planar substrate. The receptacle connector can include a plurality of terminals having termination ends aligned in common wafer plane that can be conductively terminated with the plurality of cables. The plug connector and the electrical connector are configured to establish electrical channels from the termination ends coplanar with the common wafer plan to the first and second inline terminal rows.