The present disclosure provides a connector assembly. The connector assembly includes a wire-end connector. The wire-end connector includes a wafer, a shield plate and a twin-ax cable. The wafer includes a frame and a terminal group. The terminal group is supported by the frame. The terminal group includes a signal terminal pair and a ground plate. The ground plate includes a ground terminal on both sides of the signal terminal pair. The shield plate is electrically connected to the ground plate. The shield plate includes an opening that penetrates the shield plate. The twin-ax cable includes a pair of conductors and a ground portion. The pair of conductors extend into the opening of the shield plate and are electrically connected to the signal terminal pair. The ground portion electrically connects at least one of the shield plate and the ground plate.

An electrical equipment (1) for an electrical installation is connected to an electrical grid, having at least a primary functional module (2) suitable for carrying out a current interruption function, and an additional functional module (5) for carrying out at least one function requiring a power supply. The function of the additional functional module (5) is a function requiring a power supply except for an indicator light lighting function.

An electrical equipment (1) for an electrical installation is connected to an electrical grid, having at least a primary functional module (2) suitable for carrying out a current interruption function, and an additional functional module (5) for carrying out at least one function requiring a power supply. The function of the additional functional module (5) is a function requiring a power supply except for an indicator light lighting function.

A cable-end connector, a board-end connector and an assembly thereof are provided. The assembly of the cable-end connector and the board-end connector includes a cable-end connector and a board-end connector. The cable-end connector includes an outer casing, a first contact member, a second contact member, two cables and a first locking structure. The board-end connector is used to mate with the cable-end connector, and the board-end connector includes a circuit board, a third contact member, a fourth contact member and a second locking structure. By that the first contact member and the second contact member are arranged diagonally and the third contact member and the fourth contact member are arranged diagonally, the cable-end connector and the board-end connector can be reduced in width along a lateral direction, and designed spaces respectively for the first locking structure and the second locking structure can be reserved, in turn a space of the cable-end connector and a space of the board-end connector can be used effectively.

A cable-end connector, a board-end connector and an assembly thereof are provided. The assembly of the cable-end connector and the board-end connector includes a cable-end connector and a board-end connector. The cable-end connector includes an outer casing, a first contact member, a second contact member, two cables and a first locking structure. The board-end connector is used to mate with the cable-end connector, and the board-end connector includes a circuit board, a third contact member, a fourth contact member and a second locking structure. By that the first contact member and the second contact member are arranged diagonally and the third contact member and the fourth contact member are arranged diagonally, the cable-end connector and the board-end connector can be reduced in width along a lateral direction, and designed spaces respectively for the first locking structure and the second locking structure can be reserved, in turn a space of the cable-end connector and a space of the board-end connector can be used effectively.

A backplane connector includes a housing and a number of wafers assembled to the housing. Each wafer includes a number of conductive terminals, an insulating frame and a metal shield. The housing includes an insulating housing and a metal shell fixed to the insulating housing. The insulating housing includes a number of slots for positioning the wafers. The metal shell is provided with a mating surface and a number of terminal receiving grooves. The contact portions of the conductive terminals are exposed in the corresponding terminal receiving grooves. The present disclosure improves the structural strength of the backplane connector and reduces the risk of damage the mating surface due to the push or collision of a mating connector.

A backplane connector includes a housing and a number of wafers assembled to the housing. Each wafer includes a number of conductive terminals, an insulating frame and a metal shield. The housing includes an insulating housing and a metal shell fixed to the insulating housing. The insulating housing includes a number of slots for positioning the wafers. The metal shell is provided with a mating surface and a number of terminal receiving grooves. The contact portions of the conductive terminals are exposed in the corresponding terminal receiving grooves. The present disclosure improves the structural strength of the backplane connector and reduces the risk of damage the mating surface due to the push or collision of a mating connector.

A backplane connector assembly includes a first backplane connector and a second backplane connector. The first backplane connector includes a number of first conductive terminals, a first metal shield and a second metal shield. The first conductive terminal includes a first mating portion, a first tail portion and a first connection portion extending along a mating direction. The first conductive terminals includes first differential signal terminals. The first backplane connector includes a number of shielding spaces. The second backplane connector includes second differential signal terminals and metal shield surrounding members received in the shield spaces. Compared with the prior art, the structure of the first conductive terminals of the backplane connector assembly of the present invention is simplified. By providing the shielding spaces and the metal shield surrounding members, the shielding effect of the present disclosure is improved.

A backplane connector assembly includes a first backplane connector and a second backplane connector. The first backplane connector includes a number of first conductive terminals, a first metal shield and a second metal shield. The first conductive terminal includes a first mating portion, a first tail portion and a first connection portion extending along a mating direction. The first conductive terminals includes first differential signal terminals. The first backplane connector includes a number of shielding spaces. The second backplane connector includes second differential signal terminals and metal shield surrounding members received in the shield spaces. Compared with the prior art, the structure of the first conductive terminals of the backplane connector assembly of the present invention is simplified. By providing the shielding spaces and the metal shield surrounding members, the shielding effect of the present disclosure is improved.

The present disclosure relates to a coaxial connector assembly comprising a first connector and a second connector adapted to be connected with each other, and a locking mechanism adapted to lock and unlock a connection between the first connector and the second connector. The locking mechanism includes a first locking member having at least one elastic snap-fit element and a second locking member having a locking element adapted to be snap-fitly engaged with the at least one elastic snap-fit element. The first locking member is disposed on an outer periphery of the first connector, and the second locking member is disposed on an outer periphery of the second connector. The elastic snap-fit element is constructed as a cantilever that extends axially toward a direction remote from the second connector, so that it is movable between an unlocking position and a locking position along a radial direction. In the unlocking position, the elastic snap-fit element is pressed down, so that the elastic snap-fit element is disengaged from the locking element, and in the locking position, the elastic snap-fit element springs back to its initial state, so that the elastic snap-fit element is snap-fitly engaged with the lock element.