The present disclosure provides an electrical connector including an insulating housing, a number of terminals and a lossy member. The terminals include a number of ground terminals and a number of signal terminals. The ground terminals and the signal terminals are set adjacently to each other but do not contact each other. The ground terminals do not directly contact the lossy member. As a result, installation consistency of the ground terminals can be achieved, thereby improving the electrical performance of the electrical connector.

An electrical connector includes an insulating body and a terminal module. The terminal module includes a first terminal module, a second terminal module, and a shielding piece. The first terminal module includes a number of first conductive terminals. Each first conductive terminal includes a first elastic contact arm and a first tail portion. The second terminal module includes a number of second conductive terminals. Each second conductive terminal includes a second elastic contact arm and a second tail portion. The shielding piece includes a connecting portion and a number of ground terminals. The ground terminals include a number of first ground elastic arms arranged in a same row as the first elastic contact arms and a number of second ground elastic arms arranged in a same row as the second elastic contact arms. As a result, the shielding performance of the electrical connector is improved.

The invention provides an easy lock connector with unlock structure applied to a flat wire and a circuit board. The flat wire has a notch and a ground wire on the two sides of a head end respectively. The easy-lock connector includes an upper housing, a lower housing, a rubber core and a terminal. After the notch of the flat wire is buckled by a stopper of the lower housing, by pressing a pressing member of the upper housing, the pressing member applies an external force to an elastic member of the lower housing to deform the elastic member. An extension arm of the lower housing is linked by the elastic member to cause the stopper to act in one direction so as to release the state of the stopper from locking the gap. In another embodiment, the easy-lock connector can also achieve an electromagnetic shielding effect by adding a shielding iron shell.

The invention provides an easy lock connector with unlock structure applied to a flat wire and a circuit board. The flat wire has a notch and a ground wire on the two sides of a head end respectively. The easy-lock connector includes an upper housing, a lower housing, a rubber core and a terminal. After the notch of the flat wire is buckled by a stopper of the lower housing, by pressing a pressing member of the upper housing, the pressing member applies an external force to an elastic member of the lower housing to deform the elastic member. An extension arm of the lower housing is linked by the elastic member to cause the stopper to act in one direction so as to release the state of the stopper from locking the gap. In another embodiment, the easy-lock connector can also achieve an electromagnetic shielding effect by adding a shielding iron shell.

A connector including a first body, a second body, a dielectric film and one or more conductive traces. The first body has first and second opposite sides and includes an elastomeric absorber material with ferrite or iron powder dispersed therein. The second body includes the elastomeric absorber material with ferrite or iron powder dispersed therein. The dielectric film is disposed on surfaces of the first body to extend along and between the first and second opposite sides. The one or more conductive traces are sandwiched between the second body and the dielectric film to extend along and between the first and second opposite sides. The connector can be installed into a conductive aperture, to channel RF energy through it and thus effecting an absorptive RF filter for a signal.

A connector includes a connector housing and a shield shell. A terminal electrically connected to an end part of a wire is arranged inside the connector housing. The connector housing includes an inserting portion to be inserted into a mounting hole provided in a conductive case for accommodating an inverter and an outer arrangement portion integral with the inserting portion and to be arranged outside the case. The shield shell includes a tubular covering portion for covering an outer periphery of the outer arrangement portion and is electrically connected to the case. A shield-side sealing member seals between an outer-peripheral surface of the outer arrangement portion and an inner-peripheral surface of the covering portion. The outer-peripheral surface of the outer arrangement portion has a second intrusion suppressing groove provided over the entire outer periphery of the outer arrangement portion between the shield-side sealing member and the inserting portion.

A connector includes a connector housing and a shield shell. A terminal electrically connected to an end part of a wire is arranged inside the connector housing. The connector housing includes an inserting portion to be inserted into a mounting hole provided in a conductive case for accommodating an inverter and an outer arrangement portion integral with the inserting portion and to be arranged outside the case. The shield shell includes a tubular covering portion for covering an outer periphery of the outer arrangement portion and is electrically connected to the case. A shield-side sealing member seals between an outer-peripheral surface of the outer arrangement portion and an inner-peripheral surface of the covering portion. The outer-peripheral surface of the outer arrangement portion has a second intrusion suppressing groove provided over the entire outer periphery of the outer arrangement portion between the shield-side sealing member and the inserting portion.

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.

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.