A plug comprises power contacts and a trip jumper having jumper contacts configured to make a trip connection, during a plugging action with the plug and a receptacle, with mating trip contacts in the receptacle. When the receptacle is connected to electrical power during the plugging action, a current over the trip connection can cause disconnection of a receptacle power contact from the power. A receptacle comprises receptacle power contacts and a trip circuit having receptacle trip contacts configured to make a trip connection, during a plugging action with the receptacle and plug, with mating trip contacts in the plug. When the receptacle is connected to electrical power during the plugging action, a current over the trip connection can cause disconnection of power to a receptacle power contact. A system can have an electrical device with a line cord connected to the plug.

It is aimed to prevent a noise reduction function of a twisted pair cable from being reduced near the entrances of cavities. A connector (CO) includes a twisted pair cable formed by twisting a pair of wires, female terminals (9A, 9B) connected to respective ends of both wires (W) of the twisted pair cable, a housing (15) formed with cavities (18) for individually accommodating the female terminals (9A, 9B), and a locking lance (13) deflectably arranged in the housing (15) and capable of locking the female terminals (9A, 9B). A pair of the female terminals (9A, 9B) connected to the both wires (W) of the twisted pair cable are accommodated into the cavities (18) adjacent in a Y direction and the locking lance (13) integrally and interlockably formed to straddle between the adjacent cavities (18) is formed in the adjacent cavities (18).

A passive cable adaptor for connecting a data source device with a display device is described. The adaptor has a packet-based interface connector at one end, the connector having a positive main link pin, a negative main link pin, a positive auxiliary channel pin, and a negative auxiliary channel pin. At the other end is a micro serial interface connector, wherein multimedia content is transmitted over the cable adaptor and electrical power is supplied over the cable adaptor simultaneously. The cable adaptor has an auxiliary and hot plug detect (HPD) controller utilized to map the auxiliary channel and HPD signals of the packet-based digital display to the micro serial interface ID signal.

A passive cable adaptor for connecting a data source device with a display device is described. The adaptor has a packet-based interface connector at one end, the connector having a positive main link pin, a negative main link pin, a positive auxiliary channel pin, and a negative auxiliary channel pin. At the other end is a micro serial interface connector, wherein multimedia content is transmitted over the cable adaptor and electrical power is supplied over the cable adaptor simultaneously. The cable adaptor has an auxiliary and hot plug detect (HPD) controller utilized to map the auxiliary channel and HPD signals of the packet-based digital display to the micro serial interface ID signal.

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.

A passive cable adaptor for connecting a data source device with a display device is described. The adaptor has a packet-based interface connector at one end, the connector having a positive main link pin, a negative main link pin, a positive auxiliary channel pin, and a negative auxiliary channel pin. At the other end is a micro serial interface connector, wherein multimedia content is transmitted over the cable adaptor and electrical power is supplied over the cable adaptor simultaneously. The cable adaptor has an auxiliary and hot plug detect (HPD) controller utilized to map the auxiliary channel and HPD signals of the packet-based digital display to the micro serial interface ID signal.

A passive cable adaptor for connecting a data source device with a display device is described. The adaptor has a packet-based interface connector at one end, the connector having a positive main link pin, a negative main link pin, a positive auxiliary channel pin, and a negative auxiliary channel pin. At the other end is a micro serial interface connector, wherein multimedia content is transmitted over the cable adaptor and electrical power is supplied over the cable adaptor simultaneously. The cable adaptor has an auxiliary and hot plug detect (HPD) controller utilized to map the auxiliary channel and HPD signals of the packet-based digital display to the micro serial interface ID signal.

A charger extension cable for an electric car is connected with a home circuit and a charging gun of the electric car, and the charger extension cable contains: a body. A plug connects with a home circuit, and the plug connects with an electromagnetic protection switch via a first extension part, wherein an output end of the electromagnetic protection switch connects with a measuring meter, and an output end of the measuring meter couples with a first socket via a second extension part, the first socket is applied to connect with the charging gun.

Apparatus and methods for inserting and retention testing an electrically conductive contact in an electrical connector. The method includes the following steps: manually partially inserting the contact into a hole formed inside the electrical connector; inserting the contact further into the hole by pushing the contact along an axis using an insertion tip that is aligned with the axis and that displaces in a first direction along the axis during inserting; and after inserting the contact further into the hole, testing retention of the contact inside the electrical connector by pushing the contact along the axis using a test probe that is aligned with the axis and that displaces in a second direction opposite to the first direction during retention testing. The force exerted by the test probe on the contact is less than a specified contact retention force. The method further includes generating an alert signal if the test probe displaces along the axis in the second direction by more than a specified distance during retention testing.

Apparatus and methods for inserting and retention testing an electrically conductive contact in an electrical connector. The method includes the following steps: manually partially inserting the contact into a hole formed inside the electrical connector; inserting the contact further into the hole by pushing the contact along an axis using an insertion tip that is aligned with the axis and that displaces in a first direction along the axis during inserting; and after inserting the contact further into the hole, testing retention of the contact inside the electrical connector by pushing the contact along the axis using a test probe that is aligned with the axis and that displaces in a second direction opposite to the first direction during retention testing. The force exerted by the test probe on the contact is less than a specified contact retention force. The method further includes generating an alert signal if the test probe displaces along the axis in the second direction by more than a specified distance during retention testing.