A surgical instrument including a housing, an elongated portion, and a loading unit is disclosed. The elongated portion extends distally from the housing, defines a longitudinal axis, and includes an electrical contact. The loading unit is configured to releasably engage the elongated portion. The loading unit includes an electronic component, a proximal portion including an electrical contact in electrical communication with the electronic component, and an end effector coupled to the proximal portion and configured to manipulate tissue. Engagement between the elongated portion and the loading unit causes the electrical contact of the elongated portion to engage the electrical contact of the loading unit thereby electrically connecting the elongated portion and the loading unit.

A connector includes an insulator, a plurality of pairs of terminals provided on the insulator, and a resistance element. The plurality of pairs of terminals include at least one pair of cable terminals electrically connected with a cable and at least one pair of vacant terminals that are unused. The resistance element is electrically connected between each pair of vacant terminals.

The plug shell of the electrical connector includes the accommodation portion for accommodating the contact pin and the housing that holds the contact pin, the insertion port for inserting the contact pin and the housing into the accommodation portion, the lid member for closing the insertion port, and the hold mechanism for holding the lid member. The hold mechanism includes the pedestal, on which the lid member is placed, and the pair of hold pieces, which hold the lid member on the pedestal by pressing. The pair of hold pieces press the end portions of the lid member toward the pedestal, so that thereby a stress that urges the end portions to become distant from the pedestal is generated in the lid member.

The plug shell of the electrical connector includes the accommodation portion for accommodating the contact pin and the housing that holds the contact pin, the insertion port for inserting the contact pin and the housing into the accommodation portion, the lid member for closing the insertion port, and the hold mechanism for holding the lid member. The hold mechanism includes the pedestal, on which the lid member is placed, and the pair of hold pieces, which hold the lid member on the pedestal by pressing. The pair of hold pieces press the end portions of the lid member toward the pedestal, so that thereby a stress that urges the end portions to become distant from the pedestal is generated in the lid member.

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.

An electrical plug connector having a housing and a contact carrier held inside the housing. It comprises an electrically insulating base part and at least one pair of first electrical contacts for transmitting energy and multiple pairs of second electrical contacts for transmitting data. The contacts are held in the base part and arranged so as to be distributed in a plane extending essentially perpendicular relative to the longitudinal axis of the contact elements and the contact carrier. First distance lines between the contacts of the pairs of first contacts are free of overlaps with second distance lines between the contacts of the pairs of second contacts.

A cable connector includes an outer shell having a bore extending between a mating end and a cable end. The outer shell has latch pockets. The cable connector includes a shield received in the outer shell that divides the bore into chambers. The cable connector includes contact holders received in corresponding chambers. Each contact holder includes at least one contact channel and a deflectable latch having a latching head at a distal end of the latch configured to be received in the corresponding latch pocket of the outer shell to axially secure the contact holder in the outer shell. The latch has an interference bump at an inner end of the latch configured to engage the shield to press the latching head of the latch outward. The cable connector includes contacts received in corresponding contact channels of the corresponding contact holders.

A cable connector includes an outer shell having a bore extending between a mating end and a cable end. The outer shell has latch pockets. The cable connector includes a shield received in the outer shell that divides the bore into chambers. The cable connector includes contact holders received in corresponding chambers. Each contact holder includes at least one contact channel and a deflectable latch having a latching head at a distal end of the latch configured to be received in the corresponding latch pocket of the outer shell to axially secure the contact holder in the outer shell. The latch has an interference bump at an inner end of the latch configured to engage the shield to press the latching head of the latch outward. The cable connector includes contacts received in corresponding contact channels of the corresponding contact holders.

Flexible and low cost power interconnects. The interconnect includes a plug with an insulative support and a plurality of electrical contacts mounted to exterior surfaces of the insulative support. The plug may be simply formed with molding and stamping operations. In use, the plug may be connected in an electrical assembly to support one or multiple power circuits in a compact space. A receptacle for receiving the plug may have an opening with sides bounded by rows of independent electrical contacts that may similarly be connected to one or more power circuits within a printed circuit board to which the receptacle is mounted. The plug and receptacle may be configured such that, when the receptacle connector and plug are each mounted to substrates and the connectors are mated, the substrates are spaced 6 mm, 5 mm, or less.