A fastening device to maintain a connector engaged in an electronic assembly, the fastening device including a body, a first clip member that engages in a first opening, the first clip member having a first shank that protrudes substantially perpendicularly from the body, and a first arm that protrudes the first shank towards the body, a second clip member that engages in a second opening, the second clip member having a second shank that protrudes substantially perpendicular from the body, and a pair of second arms that protrudes from the second shank towards the body, and a head affixed to the body that contacts the connector and maintains the connector engaged in the electronic assembly.

A clip for use with an electronic package, includes a frame structure with a pair of first side bars and a pair of second side bars commonly defining a receiving cavity. An ejection device is formed on one first side bar, including a stopper/kicker and a presser interlinked with each other in a co-movement manner. A latch is located around the ejection device so as to cooperate with the stopper/kicker to secure the electronic package therebetween in a vertical direction and retain the electronic package in the receiving cavity to result in an electrical assembly.

An electrical connector assembly includes: a connector housing receiving a plurality of contacts mounted to an internal substrate; a shielding shell enclosing the connector housing; and a pair of latches secured to the connector housing in a cantilevered fashion; wherein the latch has an arm secured to the substrate.

The actuator (20) of the electrical connector (11) is configured such that pressure contact between the contacts (21) and the flexible connection member (8) is canceled by the actuator (20) being arranged at an open position (A1), and the contacts (21) are brought into pressure contact with the flexible connection member (8) by the actuator (20) being arranged at a closed position (A2). A provisional holding mechanism (51) can hold the actuator (20) at a provisional hold position (A3) when the flexible connection member (8) is not connected to the electrical connector (11). The provisional holding mechanism (51) includes first engagement portions (52) provided on a housing (22), and second engagement portions (53) provided on the actuator (20).

A dual connector system includes a host circuit board and first and second electrical connectors mounted to the host circuit board. The first electrical connector has a housing having a card slot for a module circuit board and the second electrical connector has a housing having an upper mating surface for the module circuit board. The housing has a first side and an opposite second side with connector latching features and holding second contacts at the upper mating surface between the first and second sides. A dual connector module is mated to the first and second electrical connectors. A securing strap is secured to the dual connector module and has a first strap latching feature being latchably coupled to the corresponding connector latching feature to secure the dual connector module to the second electrical connector.

Apparatuses and systems associated with power provision for packages mounted to a printed circuit board are disclosed herein. In embodiments, a socket arrangement may include a header and a first bus bar, wherein the first bus bar is to extend from the header adjacent to the PCB, and is to electrically couple to a power supply contact of a component package and to a power supply connection within a proximity of a power source, wherein a power output of the power source is electrically coupled to the power supply connection. The socket arrangement may further include a second bus bar, wherein the second bus bar is to extend from the header adjacent to the PCB, and is to electrically couple to a ground contact of the component package and a ground connection within the proximity of the power source. Other embodiments may be described and/or claimed.

Provided is a connector capable of, when a closing operation of an actuator is mechanized, sufficiently applying rotational moment in a closing direction and preventing damage to the actuator. A connector (10) includes an insulator (30) into which a flat connection object is inserted, a contact group (40) that is supported by the insulator (30) and electrically connected to the connection object (20) inserted into the insulator (30), and an actuator (50) that is supported by the insulator (30) in an openable and closable manner, and also in a rotatable manner, and includes a connection object facing surface (52f) facing the flat connection object (20) in a closed state. The actuator (50) includes, on a surface opposite to the connection object facing surface (52f), a closing slope (52b) which reduces a distance to the connection object facing surface (52) as a distance from a rotation center of the actuator (50) increases.

An apparatus that is used to enclose and stack electrical components in varying configurations. The configurations are achieved by easily manipulating the way the apparatus is stacked. The stacking of apparatus' is achieved easily, and with little cost in manufacturing.

A receptacle connector is provided with a slider and a first securing metal fitting. The slider can slide between a locking position where the slider locks a plug connector and a lock releasing position where the slider is separated from the plug connector to an outer side in a longitudinal direction such that locking of the plug connector is released. The first securing metal fitting has the hook, and the slider has the first engageable part that engages with the hook to retain the slider in a selected position.

An input device may include a wire element and a moveable substrate coupled to the wire element. The moveable substrate may include various wire alignment features. The input device may further include an input surface disposed above the moveable substrate. The input device may further include various sensor electrodes coupled to the input surface. The input device may further include a haptic actuator coupled to the moveable substrate. The haptic actuator may displace the moveable substrate in a direction substantially parallel to a plane of the input surface. The wire element may return the moveable substrate to an original position. The wire alignment features may allow, in response to an applied force by the haptic actuator and to the moveable substrate, a displacement of the moveable substrate in the direction that is substantially parallel to the plane of the input surface.