An electrical connector for receiving an FFC/FPC includes an insulating housing, a plurality of conductive terminals, a pair of retaining pins, and a metal cover. The insulating housing includes a main body and a pair of shoulder parts. Each shoulder part has a guiding bump, and a pre-pressing board. An oblique-entry space is formed between the guiding bump and the pre-pressing board. The pair of retaining pins are respectively fixed in the pair of shoulder parts. A bottom end of the retaining pin is exposed from the bottom surface of the insulating housing. The metal cover is slidably disposed on the top surface of the insulating housing, and includes a top pressing plate and a pair of side sliding rails. A front end of the top pressing plate has a pressing rib. The metal cover is movably arranged between an initial position and a pressed position.

An electrical card connector includes an insulative housing, a plurality of contacts retained to the housing, a metallic shield attached to the housing and cooperating with the housing to form a receiving cavity for receiving therein an electrical card, and a card holding mechanism located beside the receiving cavity. The card holding mechanism includes a slider, a spring abutting against the slider and deformable in the front-to-back direction, and a resilient locking device. The locking device includes a securing part retained to the slider, a resilient arm extending from the securing part with a locking protrusion for engagement within a locking notch of the electrical card. The slider provides an abutment face. The free end of the locking arm is adapted to abut against the abutment face when the electrical card is inserted into or withdrawn from the receiving cavity to outwardly deflect the resilient arm.

A card edge connector includes an insulative elongated housing defining an elongated slot extending along a longitudinal direction. Two rows of contacts are disposed in the housing so as to be paired in each cross-sectional plane in a transverse direction. A pair of towers are located at two opposite ends of the housing in the longitudinal direction. A pair of ejectors/lockers are disposed in the corresponding towers and rotational about a pivot extending along the transverse direction. Each ejector has a bottom kicker adapted to intimately confront a bottom edge of the memory module for ejecting the memory module out of the housing. The kicker slightly interferes with the contacting sections of the neighboring contacts when the ejector is located at an outer position so as to be retained in position with regard to the housing.

Anchoring power pins are described herein. In one embodiment, a system includes a circuit board including a through hole, and a connector for coupling a module with the circuit board. The connector includes housing including a module-facing side to receive the module and a circuit board-facing side to couple with the circuit board. The connector includes a conductive power pin to both physically anchor the connector to the circuit board and electrically couple the module with the circuit board, the conductive power pin including a tip protruding from the circuit board-facing side of the connector to extend into a matching through hole in the circuit board.

An embodiment of a latch apparatus for a circuit board comprises a first latch body with a retention mechanism for the circuit board, a second latch body with a coupling mechanism for a connector, and a spring mechanism mechanically coupled between the first latch body and the second latch body. Other embodiments are disclosed and claimed.

A dual connector system includes a host circuit board and first and second electrical connectors for electrically connecting to a module circuit board of a dual connector module. The dual connector module has a latch at a front wall movable between a latched position and an unlatched position. The latch engages a latching feature of the first electrical connector in the latched position. The dual connector module has an ejector at the front wall operably coupled to the latch. The ejector is actuated in an actuation direction to release the latch and eject the dual connector module from the mated position to the unmated position after the latch is moved from the latched position to the unlatched position.

A motion component structure includes a motion part, an abutting part and an elastic element. The motion part includes a motion space; the abutting part is provided in the motion space; two ends of the elastic element respectively abut against the motion part and the abutting part, and the elastic element makes the motion part elastically move. Accordingly, the motion component structure can make the motion part provided at the object, and cooperate with the abutting part and the elastic element, so that the motion part and the abutting part are fastened to or unfastened from the object and the other object, so as to quickly combine and separate at least two objects, and achieve the effect of combining and separating repeatedly and quickly.

A connector for high density, high speed, and high performance electronic systems. The connector has multiple slots, each of which can receive a card. Terminals disposed on opposite sides of each slot connect the card inserted therein to a motherboard on which the connector is mounted. Each slot has a latch disposed at an end for retaining the card inserted therein when the latch is locked and releasing the card from the slot when the latch is unlocked. The connector has a reinforcing members configured to enhance the mechanical strength of the housing. Terminal tails are configured for solder ball attachments such that the terminals of adjacent slots are disposed closer. The tails are also configured such that a smaller solder area is needed on the motherboard. Such configurations improve signal integrity at higher speed and increases the tolerance of errors in the manufacturing process.

A plug connection, a first connecting part and a second connecting part of the plug connection, a patient couch, and a local coil are provided. The plug connection includes a first connecting part with at least one first contact module and a second connecting part with at least one second contact module. The first connecting part and the second connecting part are detachably connectable to one another. The first connecting part includes a housing. The first connecting part includes a displacement unit configured, during a connection of the first connecting part to the second connecting part, to move the at least one first contact module relative to the housing of the first connecting part in a direction of the at least one second contact module, in order to establish contact between the at least one first contact module and the at least one second contact module.

A dual connector system includes a host circuit board and first and second electrical connectors for electrically connecting to a module circuit board of a dual connector module. The dual connector module has a latch at a front wall movable between a latched position and an unlatched position. The latch engages a latching feature of the first electrical connector in the latched position. The dual connector module has an ejector at the front wall operably coupled to the latch. The ejector is actuated in an actuation direction to release the latch and eject the dual connector module from the mated position to the unmated position after the latch is moved from the latched position to the unlatched position.