A computing system includes a chassis and a cage. The chassis includes one or more locking hooks. The cage includes a handlebar, a bar-linkage assembly, and a crank coupled to both the handlebar and the bar-linkage assembly. Rotating the handlebar from an unlocked position to a locked position lowers the cage relative to the chassis until the cage is locked in the one or more locking hooks of the chassis.

A microprocessor heat sink fastener assembly, comprising a base to couple to a heat sink a retention nut to be received by a cavity of the base, and a retention clip to be attached to the base and to be cantilevered therefrom. The retention clip is to engage with a latching structure extending from a latching structure of a retention plate.

Examples of an installation module for installing a circuit-based component are described. The installation module comprises a base plate having a pair of longitudinal edges and a pair of lateral edges. The installation module may further include a supporting element to support a circuit-based component installed within the installation module. The installation module may further include first wall, a second wall and a back wall. In an example, a retaining element to retain the circuit-based component when installed, may be provided on one of the first wall and the second wall. The back wall may further include a tab which extends from a longitudinal edge of the back wall, and when pulled, is to disengage the installation module from a chassis of a computing device.

Provided is an expansion card installation module including an expansion-card bracket, an operating element, a stopper, and a driving component. The operating element is pivoted on the expansion-card bracket. The stopper is slidably disposed on the expansion-card bracket and is located at a stop position or a non-stop position. The stopper at the stop position is adapted to stop an expansion card in the expansion-card bracket, and the stopper at the non-stop position releases the expansion card, such that the expansion card is allowed to be removed from the expansion-card bracket. The driving component is movably disposed on the expansion-card bracket. The operating element is adapted to push against the stopper to move the stopper from the stop position to the non-stop position, and the driving component is adapted to position the stopper at the non-stop position. A server is also provided.

Methods, apparatus, systems, and articles of manufacture to improve pin contact are disclosed. An apparatus disclosed herein includes a back plate, a circuit board disposed between the back plate and a socket, and a spring sheet disposed between the back plate and the circuit board.

A circuit board includes a board body, a card slot, a release structure, and a transmission mechanism. The card slot is disposed on the board body and adapted for inserting an expansion card. The release structure is rotatably disposed beside the card slot. The transmission mechanism includes a contact part and a stressed part that are linked to each other, wherein the contact part is connected to the release structure. When the stressed part receives an external force, the contact part is moved correspondingly, so that the release structure is rotated relative to the card slot, thereby releasing the expansion card.

A latch mechanism for securing an expansion card assembly in a computer chassis includes a lever, a stop member, a rotary latch, a first biasing structure, and a second biasing structure. The lever includes a latching end and an opposing pinned end. The stop member extends from the pinned end. The rotary latch is connected to the latching end and includes a receiving chamber and a hook structure. The hook structure includes a notch for receiving a stop pin. The first biasing structure extends from the lever into the receiving chamber and is configured to urge the rotary latch into a locked position. The second biasing structure is configured to urge the lever about the pinned end to an open position.

Provided is an engaging driving structure having a first driving fastener, a second driving fastener and a linking unit. The second driving fastener is disposed beside the first driving fastener. The linking unit is disposed between the first driving fastener and the second driving fastener and adapted to movably connect the first driving fastener and the second driving fastener. Therefore, the engaging driving structure is easy to use, labor-saving, and convenient.

A coupling for connecting a circuit board to a mount with a fastener. The mount may be connected to a component. The fastener includes a first snap-fit connection formation for establishing a snap-fit connection with a second snap-fit connection formation provided on the mount. When connected, the fastener clamps the circuit board against the mount. The fastener further includes a first engagement formation configured to engage with a second engagement formation on the mount for bracing the snap-fit connection.

Electronic device fastening systems that enable one or more electronic devices to be reliably and quickly secured on a host board and electronic systems made of the same. In a specific exemplary embodiment, a retainer clip spans across the width of one or more electronic devices, engages with the board and snaps into place. The clip includes one or retaining posts such that when the clip engages the board, the one or more retaining posts align and engage with a predefined mounting feature of a corresponding one of the one or more electronic devices, thereby securing the electronic device in place to restrict horizontal, lateral, and vertical movement of the electronic device.