A modular electrical connector with separately shielded signal conductor pairs. The connector may be assembled from modules, each containing a pair of signal conductors with surrounding partially or fully conductive material. Modules of different sizes may be assembled into wafers, which are then assembled into a connector. Wafers may include lossy material. In some embodiments, shielding members of two mating connectors may each have compliant members along their distal portions, such that, the shielding members engage at points of contact at multiple locations, some of which are adjacent the mating edge of each of the mating shielding members.

A modular electrical connector with separately shielded signal conductor pairs. The connector may be assembled from modules, each containing a pair of signal conductors with surrounding partially or fully conductive material. Modules of different sizes may be assembled into wafers, which are then assembled into a connector. Wafers may include lossy material. In some embodiments, shielding members of two mating connectors may each have compliant members along their distal portions, such that, the shielding members engage at points of contact at multiple locations, some of which are adjacent the mating edge of each of the mating shielding members.

An electrical connector includes an elongate insulative housing defining a central slot extending along a longitudinal direction, and two rows of contacts disposed by two sides of the central slot. The housing forms a front receiving cavity to receive the corresponding mating tongue of the complementary connector, and a rear receiving cavity to receive the corresponding insulators wherein each insulator is integrally formed with each row of contacts via insert-molding for completing the whole contact module. Each grounding contact is equipped with the corresponding EMI absorber before being insert-molded within the insulator so as to have the corresponding EMI absorber also integrally formed with the insulator.

A connecting device configured to be installed on a first coaxial cable connector to facilitate connection of the first connector to a second connector and to maintain ground continuity across the connectors. In some embodiments, the connecting device includes a grounding element disposed in a gripping member, the grounding element including one or more projections configured to extend beyond an end of the gripping member to conductively engage an outer surface of the second connector.

Input/output (I/O) connectors (1) for conducting data at high data rates, (e.g. 112 gigabits per second or more) are provided with protective shields (4, 5, 6) to provide increased mechanical strength and signal integrity.

Input/output (I/O) connectors (1) for conducting data at high data rates, (e.g. 112 gigabits per second or more) are provided with protective shields (4, 5, 6) to provide increased mechanical strength and signal integrity.

The present invention provides a method for designing USB floating with low electromagnetic interference, especially in a scenario in which a distance between a pin and a metal housing of a USB interface of a terminal device is increasingly small. A first plug and a second plug are connected by using a connection cable having a first shield layer and a second shield layer. The first shield layer and the second shield layer overlap and there is no electrical connection between the first shield layer and the second shield layer. One end of the first shield layer is connected to a metal housing of the first plug, and the other end is suspended. One end of the second shield layer is connected to a metal housing of the second plug, and the other end is suspended. In addition, a metal housing of a first socket and a metal housing of a second socket may be connected to a housing of the terminal device or a housing of an adapter by using a capacitive component, thereby helping the terminal device reduce a short circuit risk and radiation.

The present invention provides a method for designing USB floating with low electromagnetic interference, especially in a scenario in which a distance between a pin and a metal housing of a USB interface of a terminal device is increasingly small. A first plug and a second plug are connected by using a connection cable having a first shield layer and a second shield layer. The first shield layer and the second shield layer overlap and there is no electrical connection between the first shield layer and the second shield layer. One end of the first shield layer is connected to a metal housing of the first plug, and the other end is suspended. One end of the second shield layer is connected to a metal housing of the second plug, and the other end is suspended. In addition, a metal housing of a first socket and a metal housing of a second socket may be connected to a housing of the terminal device or a housing of an adapter by using a capacitive component, thereby helping the terminal device reduce a short circuit risk and radiation.

An interface arrangement (1) includes a plug connector (4) arranged on an interface board (3). Furthermore, the interface arrangement (1) includes an electrically conductive cover (10) at least partially surrounding the plug connector (4). The electrically conductive cover (10) is adapted to seal an interface opening of the housing, in which opening the plug connector (4) can be arranged, against electromagnetic radiation. The electrically conductive cover (10) includes at least one tab (19) with a latching device. The interface board (3) includes at least one receiving device, which is adapted to receive the at least one tab (19) and to latch with the latching device. A computer system with such an interface arrangement (1), and a method for assembling such an interface arrangement (1).

A first connector includes a first case and a screw member. The first case includes a first fitting part having a tubular shape. The screw member includes a first screw part and is disposed opposite to an outer peripheral surface of the first fitting part at an interval and held rotatably about a screw axis relative to the first case. The screw axis is aligned with a direction in which the first connector and a second connector are inserted and removed relative to the second connector. The second connector includes a second case and a second screw part. The second case includes a second fitting part having a tubular shape. The second screw part is provided in a connector fixation wall to which the second case is fixed and to which the first case is fixed outside of an outer peripheral surface of the second fitting part.