Embodiments described herein relate to a system for securing a computing device component. The system may include the computing device component that includes: a base component comprising a pass through hole, a rotating member coupled to the base component and adapted to rotate about an axis, a lever body that includes: a base-holding portion adapted to be positioned around the base component, and a lever extension at a first end of the lever body and extending substantially orthogonally in a direction substantially orthogonal to the axis, a lever locking component coupled to the lever body and that includes: a locking actuator, and an inserting component adapted to insert into the pass-through hole when the locking actuator is in a locked position, wherein when a force is applied to the lever extension, the base component rotates about the axis.

An ejector may be provided. The ejector may comprise a pawl, a trigger, and a handle. The pawl may be configured to rotate relative to a line card about a first axis. The pawl may comprise a pawl concavity. The trigger may be configured to rotate relative to the line card about a second axis. The trigger may comprise a trigger catch and a trigger lever. The trigger catch may be configured to engage the pawl concavity. The handle may be connected to the pawl and configured to rotate relative to the pawl about a third axis. The trigger catch may be configured to engage the pawl concavity to inhibit rotation of the pawl about the first axis. The trigger catch may be configured to disengage the pawl concavity and to allow rotation of the pawl about the first axis.

A rotary motion structure comprises a limiting member and a rotating member. The limiting member defines a mounting portion; and the rotating member is rotatably provided on the limiting member and includes a shaft portion, which is provided through the mounting portion. Accordingly, the rotary motion structure described above is preferably applied to form a handle device having a positioning function, in which the rotating member is rotated relative to the limiting member so that the rotating member can have the positioning efficacy of automatic positioning, frictional positioning, temporary positioning, or fixed positioning.

A connection mechanism is provided with a circuit board that replaces internal chassis cabling to multiple electronic devices. In use, the motion of a lever of the connection mechanism drives a carrier of the circuit board in one direction to make an electrical connection at a side of the circuit board. Continued motion of the lever drives the carrier downward to make an additional electrical connections at the bottom of the circuit board.

A method is disclosed for manufacturing an electronic component carrier. The method comprises positioning a header of a frame between opposing attachment arms extending outwardly for attaching an electronic component for seating within the frame. Further, latching members of a latching mechanism of the frame are positioned at a distal end of each of the attachment arms for releaseably seating the electronic component. The attachment arms are resiliently flexible such that the latching members bend to a release position and resiliently return to a grasping position for releasing and grasping the electronic component. Handling levers are positioned for removably mating the electronic component to a connector on a circuit board. The handling levers extend upwardly through an outer casing housing the circuit board when in an open position, and the handling levers are substantially parallel with a top surface of the header when in a closed position.

Apparatuses for expansion device retention. Specifically, the disclosed apparatuses implement retention mechanisms capable of being temporarily fastened to expansion slots whereat expansion devices may be installed. By fastening to the expansion slots, any permanent redesign and/or modification to the printed circuit boards, whereon the expansion slots may be mounted, may be minimized (if not eliminated). Amongst the disclosed apparatuses, an attachable hockey stick is introduced for expansion devices lacking a hockey stick shaped feature, where the attachable hockey stick engages with the aforementioned retention mechanisms to secure the expansion devices during, for example, shock events.

A pull aid structure includes a handle; a connecting element movably disposed at the handle; and a positioning element disposed at the handle and movably coupled to the connecting element. The pull aid structure enables a user to place the connecting element on an object, rotate the handle to fasten another object, confine the positioning element to the connecting element, and compress an elastic element, so as to couple together the two objects. To remove one of the objects, the user separates the positioning element and the connecting element to thereby separate the two objects, thereby achieving quick coupling and ease of removal.

A locking mechanism for securing different expansion cards in a slot of a chassis of a computing device is disclosed. The locking mechanism includes a base and a main body. The base is coupled to the chassis and movable between an open position and a closed position. The main body is coupled to the base and movable between a first orientation and a second orientation. When the base is in the closed position and the main body is in the first orientation, a first mating feature of the main body engages an expansion card having a first form factor inserted into the slot. When the base is in the closed position and the main body is in the second orientation, the second mating feature engages an expansion card having a second form factor inserted into the slot of the chassis.

Extendable lever arms can be used to facilitate insertion and removal of a sled into and out of a chassis. Each extendable lever can include a rotatable body, a primary arm, and a secondary arm. The rotatable body can be rotatably coupled to the housing of the sled, and can optionally include latching elements to secure the sled within the chassis, as well as optional removal features to facilitate disengaging the sled from the chassis. The secondary arm can be coupled to the primary arm to move between a retracted position and an extended position. When in the retracted position, the secondary arm can be positioned adjacent to the primary arm to avoid blocking access to ports of the sled. When in the extended position, however, the secondary arm can be positioned to provide a longer lever arm to facilitate insertion and removal of the sled.

A connector gap between a module connector mating surface and the backplane connector of a chassis may be eliminated through a mechanism that forcefully pushes (or pulls) the module towards the backplane and/or forcefully pushes (or pulls) the backplane toward the module. A spring-loaded or resilient element may be used to fasten the module in a way that effectively fills any designed-in and tolerance-induced gap in the connector interface, allowing the connector to fully seat. In addition, a gasket or other compressible member may be included at the connector mating interface. The gap in the connector interface may be reduced by introducing adjustable card cage members that are capable of being set during the assembly or manufacturing process using special alignment fixtures. The gap in the connector interface may also be reduced by introducing a higher tolerance capable manufacturing process, such as machining, to the card cage sub-assembly.