A contact for an electrical connector includes a contact section and a connecting section. The connecting section is separable from the contact section.

A self-locking connector provides an electrical connection between sources, equipment, devices, and the like. The self-locking connector generally includes first and second connector components with first and second housings that include corresponding electrically conductive elements, first and second magnetic elements, and first and second lock elements. One housing includes stationary and movable housing components. The connector components are brought into a coupled state with the corresponding electrically conductive elements providing an electrical connection. As the connector components are brought into the coupled state, the movable housing component automatically moves and brings the locking elements into locked engagement. The magnetic elements urge the connector components in the coupled state and the locking elements in locked engagement. The movable housing component is manually moved to bring the lock components out of locked engagement and the connector components out of the coupled state to break the electrical connection.

A self-locking connector provides an electrical connection between sources, equipment, devices, and the like. The self-locking connector generally includes first and second connector components with first and second housings that include corresponding electrically conductive elements, first and second magnetic elements, and first and second lock elements. One housing includes stationary and movable housing components. The connector components are brought into a coupled state with the corresponding electrically conductive elements providing an electrical connection. As the connector components are brought into the coupled state, the movable housing component automatically moves and brings the locking elements into locked engagement. The magnetic elements urge the connector components in the coupled state and the locking elements in locked engagement. The movable housing component is manually moved to bring the lock components out of locked engagement and the connector components out of the coupled state to break the electrical connection.

A plug-in connector comprises a first connecting part with at least one first contact element and a second connecting part with at least one second contact element. The first connecting part is configured for being connected with and disconnected from the second connecting part. The first connecting part comprises a latching element with a snap-in member, and the second connecting part comprises a retaining sleeve configured for accepting the latching element. The latching pin and the retaining sleeve constitute a mechanical mechanism provided in addition to the at least one first contact element and the at least one second contact element. A mechanical interaction between the latching pin and the retaining sleeve enforces a predetermined motion pattern of the at least one first contact element relative to the at least one second contact element during a process of connecting or disconnecting the first connecting part and the second connecting part.

A plug-in connector comprises a first connecting part with at least one first contact element and a second connecting part with at least one second contact element. The first connecting part is configured for being connected with and disconnected from the second connecting part. The first connecting part comprises a latching element with a snap-in member, and the second connecting part comprises a retaining sleeve configured for accepting the latching element. The latching pin and the retaining sleeve constitute a mechanical mechanism provided in addition to the at least one first contact element and the at least one second contact element. A mechanical interaction between the latching pin and the retaining sleeve enforces a predetermined motion pattern of the at least one first contact element relative to the at least one second contact element during a process of connecting or disconnecting the first connecting part and the second connecting part.

A multi-pole electric connection device is described, comprising a multi-pole male electric connection device and a multi-pole female electric connection device, these devices comprising a front capsule comprising a seat inside which a module-holder core is adapted to be inserted, comprising suitable recesses designed to contain contact modules for contacts of an electric type and/or for transporting signals, the front capsule and the module-holder core being made of conductive material to keep a screening between the contacts and to keep unaltered the characteristics of the transmitted signals, these devices being mutually connectable by means of the respective male contacts coupled with the female contacts.

A multi-pole electric connection device is described, comprising a multi-pole male electric connection device and a multi-pole female electric connection device, these devices comprising a front capsule comprising a seat inside which a module-holder core is adapted to be inserted, comprising suitable recesses designed to contain contact modules for contacts of an electric type and/or for transporting signals, the front capsule and the module-holder core being made of conductive material to keep a screening between the contacts and to keep unaltered the characteristics of the transmitted signals, these devices being mutually connectable by means of the respective male contacts coupled with the female contacts.

The present disclosure provides a connector which is a combination of at least one power pin, one plastic member, and one signal pin, wherein the power pin includes a columnar metal block, each plastic member is connected to the columnar metal block at side surface, each signal pin is attached to a side surface of the plastic member, and extends to two bottom surfaces of the plastic member to form contact surfaces with predetermined areas on the two bottom surfaces; wherein, the contact surface on first bottom surface of the plastic member is flush with first bottom surface of the metal block, and the contact surface on second bottom surface of the plastic member is flush with second bottom surface of the metal block.

Embodiments of a high-frequency electrical distributor device may have an input end with a connector of a first connector type, and an output end with at least two connectors of at least one second connector type which is different from the first connector type. Embodiments may further include a distributor region between the connector at the input end and the connector at the output end. The connector at the input end has at least two differential contact element pairs. The distributor region distributes the contact element pairs of the connector at the input end to the connectors at the output end.

Embodiments of a high-frequency electrical distributor device may have an input end with a connector of a first connector type, and an output end with at least two connectors of at least one second connector type which is different from the first connector type. Embodiments may further include a distributor region between the connector at the input end and the connector at the output end. The connector at the input end has at least two differential contact element pairs. The distributor region distributes the contact element pairs of the connector at the input end to the connectors at the output end.